PMID-sentid Pub_year Sent_text comp_official_name comp_offset protein_name organism prot_offset 31243862-3 2019 Insight into the constitution and reactivity of these bimetallic mixtures revealed the formation of highly active lithium diorganodialkoxyzincates of type [R"2 Zn(OR)2 Li2 ]. lithium diorganodialkoxyzincates 114-146 ATP binding cassette subfamily A member 12 Homo sapiens 168-171 31442041-0 2019 Theoretical Study of Cationic Alkali Dimers Interacting with He: Li2+-He and Na2+-He van der Waals Complexes. Helium 61-63 ATP binding cassette subfamily A member 12 Homo sapiens 65-68 31339690-3 2019 The soluble Li2Sx polysulfides react with the additive to create insoluble polysulfides with a lithium byproduct; this byproduct reacts with the Li-metal anode to create an anode passivation layer that is a good Li+ conductor, which allows for safe and rapid plating/stripping of lithium metal with a low impedance. polysulfide 18-30 ATP binding cassette subfamily A member 12 Homo sapiens 12-15 31339690-3 2019 The soluble Li2Sx polysulfides react with the additive to create insoluble polysulfides with a lithium byproduct; this byproduct reacts with the Li-metal anode to create an anode passivation layer that is a good Li+ conductor, which allows for safe and rapid plating/stripping of lithium metal with a low impedance. Lithium 95-102 ATP binding cassette subfamily A member 12 Homo sapiens 12-15 31339690-3 2019 The soluble Li2Sx polysulfides react with the additive to create insoluble polysulfides with a lithium byproduct; this byproduct reacts with the Li-metal anode to create an anode passivation layer that is a good Li+ conductor, which allows for safe and rapid plating/stripping of lithium metal with a low impedance. lithium metal 280-293 ATP binding cassette subfamily A member 12 Homo sapiens 12-15 30964679-1 2019 By introduction of K+, Rb+, and Cs+ cations into the classical commercial nonlinear optical crystal LiB3O5 (LBO), the series of novel mixed-alkali-metal borates Li2.6K0.4[B5O8(OH)2] (K-LBO), Li2.85Rb0.15[B5O8(OH)2] (Rb-LBO), and Li2.9Cs0.1[B5O8(OH)2] (Cs-LBO) have been obtained under hydrothermal conditions. Rubidium 23-26 ATP binding cassette subfamily A member 12 Homo sapiens 161-164 31197934-3 2019 Metal (M)-mixed SiO shows great promise to address these issues by reactivating Li2 O through the reaction M+Li2 O MOx +Li+ , which is the inverse reaction to that occurring at MOx anodes. Metals 0-5 ATP binding cassette subfamily A member 12 Homo sapiens 80-83 31197934-3 2019 Metal (M)-mixed SiO shows great promise to address these issues by reactivating Li2 O through the reaction M+Li2 O MOx +Li+ , which is the inverse reaction to that occurring at MOx anodes. Metals 0-5 ATP binding cassette subfamily A member 12 Homo sapiens 109-112 31197934-3 2019 Metal (M)-mixed SiO shows great promise to address these issues by reactivating Li2 O through the reaction M+Li2 O MOx +Li+ , which is the inverse reaction to that occurring at MOx anodes. silicon monoxide 16-19 ATP binding cassette subfamily A member 12 Homo sapiens 80-83 31197934-3 2019 Metal (M)-mixed SiO shows great promise to address these issues by reactivating Li2 O through the reaction M+Li2 O MOx +Li+ , which is the inverse reaction to that occurring at MOx anodes. silicon monoxide 16-19 ATP binding cassette subfamily A member 12 Homo sapiens 109-112 31197934-10 2019 In addition, coarsening of the nano-Sn material reduces the inverse conversion reactivity of Sn/Li2 O and subsequently results in rapid capacity fading. Tin 36-38 ATP binding cassette subfamily A member 12 Homo sapiens 96-99 31197934-11 2019 The quantitative analysis indicates that, in contrast to transition metals, the alloying and dealloying nature of Sn gives a 50 % improvement in reversible capacity, attributed to Sn/Li2 O. Tin 114-116 ATP binding cassette subfamily A member 12 Homo sapiens 183-186 30964679-1 2019 By introduction of K+, Rb+, and Cs+ cations into the classical commercial nonlinear optical crystal LiB3O5 (LBO), the series of novel mixed-alkali-metal borates Li2.6K0.4[B5O8(OH)2] (K-LBO), Li2.85Rb0.15[B5O8(OH)2] (Rb-LBO), and Li2.9Cs0.1[B5O8(OH)2] (Cs-LBO) have been obtained under hydrothermal conditions. Cesium 32-35 ATP binding cassette subfamily A member 12 Homo sapiens 161-164 30964679-1 2019 By introduction of K+, Rb+, and Cs+ cations into the classical commercial nonlinear optical crystal LiB3O5 (LBO), the series of novel mixed-alkali-metal borates Li2.6K0.4[B5O8(OH)2] (K-LBO), Li2.85Rb0.15[B5O8(OH)2] (Rb-LBO), and Li2.9Cs0.1[B5O8(OH)2] (Cs-LBO) have been obtained under hydrothermal conditions. lbo 108-111 ATP binding cassette subfamily A member 12 Homo sapiens 161-164 30964679-1 2019 By introduction of K+, Rb+, and Cs+ cations into the classical commercial nonlinear optical crystal LiB3O5 (LBO), the series of novel mixed-alkali-metal borates Li2.6K0.4[B5O8(OH)2] (K-LBO), Li2.85Rb0.15[B5O8(OH)2] (Rb-LBO), and Li2.9Cs0.1[B5O8(OH)2] (Cs-LBO) have been obtained under hydrothermal conditions. Cesium 32-34 ATP binding cassette subfamily A member 12 Homo sapiens 161-164 30673160-3 2019 Herein, by soaking single crystals of Li2 ([18]crown-6)3 [Ni(dmit)2 ]2 (H2 O)4 (1) in an aqueous solution containing K+ , we succeeded in complete ion exchange of the Li+ ions in 1 with K+ ions in the solution, while maintaining the crystalline state of the material. dmit) 61-66 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 31042888-5 2019 In this article, we consider the He-Li2 cluster where an ab initio examination of multimode dynamics during the electronic decay is feasible. Helium 33-35 ATP binding cassette subfamily A member 12 Homo sapiens 36-39 31042888-7 2019 In He droplets, Li2 can be formed in both the ground X1Sigmag + and the first excited a3Sigmau + states. Helium 3-5 ATP binding cassette subfamily A member 12 Homo sapiens 16-19 30924638-4 2019 Owing to the strong oxygen adsorption of SnO2, oxygen-reduction reactions tend to occur on composite cathode surfaces, resulting in the formation of flake-like discharge products of Li2- xO2 less than 10 nm in thickness rather than toroidal particles of several hundred nanometers. Tin(IV) oxide 41-45 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 30924638-4 2019 Owing to the strong oxygen adsorption of SnO2, oxygen-reduction reactions tend to occur on composite cathode surfaces, resulting in the formation of flake-like discharge products of Li2- xO2 less than 10 nm in thickness rather than toroidal particles of several hundred nanometers. Oxygen 47-53 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 30673160-3 2019 Herein, by soaking single crystals of Li2 ([18]crown-6)3 [Ni(dmit)2 ]2 (H2 O)4 (1) in an aqueous solution containing K+ , we succeeded in complete ion exchange of the Li+ ions in 1 with K+ ions in the solution, while maintaining the crystalline state of the material. Water 72-76 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 30667554-2 2019 The Li2 derivatives displayed a bridging amide between two Li atoms within the fluorenide-NHC pocket, whereas the Na2 and K2 analogues displayed extended solid-state structures with the fluorenide-NHC ligand chelating one alkali metal centre. Amides 41-46 ATP binding cassette subfamily A member 12 Homo sapiens 4-7 30839031-1 2019 Solvated lithium closo-dodecaborate, Li2B12H12 with tetrahydrofuran and acetonitrile, show unexpected melting below 150 C. This feature has been explored to melt-infiltrate Li2B12H12 in a nanoporous SiO2 scaffold. lithium closo-dodecaborate 9-35 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 30839031-1 2019 Solvated lithium closo-dodecaborate, Li2B12H12 with tetrahydrofuran and acetonitrile, show unexpected melting below 150 C. This feature has been explored to melt-infiltrate Li2B12H12 in a nanoporous SiO2 scaffold. tetrahydrofuran 52-67 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 30839031-1 2019 Solvated lithium closo-dodecaborate, Li2B12H12 with tetrahydrofuran and acetonitrile, show unexpected melting below 150 C. This feature has been explored to melt-infiltrate Li2B12H12 in a nanoporous SiO2 scaffold. acetonitrile 72-84 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 30839031-1 2019 Solvated lithium closo-dodecaborate, Li2B12H12 with tetrahydrofuran and acetonitrile, show unexpected melting below 150 C. This feature has been explored to melt-infiltrate Li2B12H12 in a nanoporous SiO2 scaffold. Silicon Dioxide 200-204 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 30667554-2 2019 The Li2 derivatives displayed a bridging amide between two Li atoms within the fluorenide-NHC pocket, whereas the Na2 and K2 analogues displayed extended solid-state structures with the fluorenide-NHC ligand chelating one alkali metal centre. fluorenide-nhc 79-93 ATP binding cassette subfamily A member 12 Homo sapiens 4-7 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Tritium 69-76 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Tritium 145-152 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Oxygen 173-179 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Tritium 145-152 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Oxygen 235-241 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30667554-2 2019 The Li2 derivatives displayed a bridging amide between two Li atoms within the fluorenide-NHC pocket, whereas the Na2 and K2 analogues displayed extended solid-state structures with the fluorenide-NHC ligand chelating one alkali metal centre. fluorenide 79-89 ATP binding cassette subfamily A member 12 Homo sapiens 4-7 30783645-4 2019 Based on the defect properties and migration process, a model of the tritium trapping and migration mechanisms in Li2O is proposed: (1) the bred tritium is first trapped by oxygen vacancies; (2) subsequently the tritium detrapped from oxygen vacancies is retrapped by lithium vacancies, forming T substituents; and (3) the T substituents hop along the Li lattice. Lithium 268-275 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 30485689-4 2019 The thin g-C3 N4 /GS interlayer significantly suppresses diffusion of the dissolved polysulfide species (Li2 Sx ; 2<x<=8) from the cathode to the anode, as proven by using an H-type glass cell divided by a g-C3 N4 /GS-coated separator. polysulfide 84-95 ATP binding cassette subfamily A member 12 Homo sapiens 105-108 30485689-7 2019 According to XPS results, the anchoring of the g-C3 N4 /GS interlayer to Li2 Sx can be attributed to a coefficient chemical binding effect of g-C3 N4 and graphene on long-chain polysulfides. g-c3 n4 47-54 ATP binding cassette subfamily A member 12 Homo sapiens 73-76 30288931-4 2019 The ion- and electron-conductive Li2 O-Zn middle layer can be ingeniously introduced by means of the poor reversed conversion reaction between ZnO and Li+ ions after the first cycle. Zinc Oxide 143-146 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 30288931-5 2019 The resultant Si/Li2 O-Zn/C trilayer composite film delivers a high reversible capacity of 1536 mAh g-1 after 800 cycles at a current density of 1.0 A g-1 and a long high-rate cycling stability (1400 mAh g-1 after 6000 cycles even at a high current density of 10.0 A g-1 ). Silicon 14-16 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 30485689-7 2019 According to XPS results, the anchoring of the g-C3 N4 /GS interlayer to Li2 Sx can be attributed to a coefficient chemical binding effect of g-C3 N4 and graphene on long-chain polysulfides. Graphite 154-162 ATP binding cassette subfamily A member 12 Homo sapiens 73-76 30288931-5 2019 The resultant Si/Li2 O-Zn/C trilayer composite film delivers a high reversible capacity of 1536 mAh g-1 after 800 cycles at a current density of 1.0 A g-1 and a long high-rate cycling stability (1400 mAh g-1 after 6000 cycles even at a high current density of 10.0 A g-1 ). Carbon 26-27 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 30485689-7 2019 According to XPS results, the anchoring of the g-C3 N4 /GS interlayer to Li2 Sx can be attributed to a coefficient chemical binding effect of g-C3 N4 and graphene on long-chain polysulfides. polysulfide 177-189 ATP binding cassette subfamily A member 12 Homo sapiens 73-76 33005285-0 2019 Low-Temperature Rotational Tunneling of Tetrahydroborate Anions in Lithium Benzimidazolate-Borohydride Li2(bIm)BH4. tetrahydroborate 40-56 ATP binding cassette subfamily A member 12 Homo sapiens 103-106 33005285-1 2019 To investigate the dynamical properties of the novel hybrid compound, lithium benzimidazolate-borohydride Li2(bIm)BH4 (where bIm denotes a benzimidazolate anion, C7N2H5 -), we have used a set of complementary techniques: neutron powder diffraction, ab initio density functional theory calculations, neutron vibrational spectroscopy, nuclear magnetic resonance, neutron spin echo, and quasi-elastic neutron scattering. benzimidazolate 78-93 ATP binding cassette subfamily A member 12 Homo sapiens 106-109 33005285-0 2019 Low-Temperature Rotational Tunneling of Tetrahydroborate Anions in Lithium Benzimidazolate-Borohydride Li2(bIm)BH4. lithium benzimidazolate-borohydride 67-102 ATP binding cassette subfamily A member 12 Homo sapiens 103-106 33005285-3 2019 This motion is facilitated by the unusual coordination of tetrahedral BH4 - anions in Li2(bIm)BH4: each anion has one of its H atoms anchored within a nearly square hollow formed by four coplanar Li+ cations, while the remaining -BH3 fragment extends into a relatively open space, being only loosely coordinated to other atoms. sapropterin 70-73 ATP binding cassette subfamily A member 12 Homo sapiens 86-89 33005285-3 2019 This motion is facilitated by the unusual coordination of tetrahedral BH4 - anions in Li2(bIm)BH4: each anion has one of its H atoms anchored within a nearly square hollow formed by four coplanar Li+ cations, while the remaining -BH3 fragment extends into a relatively open space, being only loosely coordinated to other atoms. BH 3 230-233 ATP binding cassette subfamily A member 12 Homo sapiens 86-89 33005285-1 2019 To investigate the dynamical properties of the novel hybrid compound, lithium benzimidazolate-borohydride Li2(bIm)BH4 (where bIm denotes a benzimidazolate anion, C7N2H5 -), we have used a set of complementary techniques: neutron powder diffraction, ab initio density functional theory calculations, neutron vibrational spectroscopy, nuclear magnetic resonance, neutron spin echo, and quasi-elastic neutron scattering. lithium benzimidazolate-borohydride 70-105 ATP binding cassette subfamily A member 12 Homo sapiens 106-109 33005285-1 2019 To investigate the dynamical properties of the novel hybrid compound, lithium benzimidazolate-borohydride Li2(bIm)BH4 (where bIm denotes a benzimidazolate anion, C7N2H5 -), we have used a set of complementary techniques: neutron powder diffraction, ab initio density functional theory calculations, neutron vibrational spectroscopy, nuclear magnetic resonance, neutron spin echo, and quasi-elastic neutron scattering. bim 110-113 ATP binding cassette subfamily A member 12 Homo sapiens 106-109 30320950-4 2018 With M=Li, Li2 CO3 precipitates and the neutral 1 is liberated such that it can be reduced again to establish a catalytic cycle. co3 15-18 ATP binding cassette subfamily A member 12 Homo sapiens 11-14 30230058-1 2018 Two new borate fluorides, Li2 BaSc(BO3 )2 F and LiBa2 Pb(BO3 )2 F, with layered structures featuring special Li-O/F configurations have been successfully prepared by the high-temperature solution method. borate fluorides 8-24 ATP binding cassette subfamily A member 12 Homo sapiens 26-29 30397995-4 2018 It is shown that a spontaneous and prompt chemical reaction is triggered once Li contact is made, leading to expansion and pulverization of LiCoO2 and ending with the final reaction products of Li2 O and Co metal. licoo2 140-146 ATP binding cassette subfamily A member 12 Homo sapiens 194-197 30475459-6 2018 Tertiary amine layer (TAL) polymerized on a polypropylene separator selectively coordinates with the dissolved high-order Li2 Sx in the cathode. tertiary amine 0-14 ATP binding cassette subfamily A member 12 Homo sapiens 122-125 30475459-6 2018 Tertiary amine layer (TAL) polymerized on a polypropylene separator selectively coordinates with the dissolved high-order Li2 Sx in the cathode. L-talo-gamma-lactone 22-25 ATP binding cassette subfamily A member 12 Homo sapiens 122-125 30475459-6 2018 Tertiary amine layer (TAL) polymerized on a polypropylene separator selectively coordinates with the dissolved high-order Li2 Sx in the cathode. Polypropylenes 44-57 ATP binding cassette subfamily A member 12 Homo sapiens 122-125 30009540-0 2018 Li2 S- or S-Based Lithium-Ion Batteries. Lithium 18-25 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 30230058-2 2018 Li2 BaSc(BO3 )2 F contains the first reported 2 [Li2 (BO3 )2 F] double layers that are evolved from 2 [Be2 BO3 F2 ] single layers in KBe2 BO3 F2 through substituting BeO4 with the LiO3 F tetrahedra. beo4 170-174 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 30230058-2 2018 Li2 BaSc(BO3 )2 F contains the first reported 2 [Li2 (BO3 )2 F] double layers that are evolved from 2 [Be2 BO3 F2 ] single layers in KBe2 BO3 F2 through substituting BeO4 with the LiO3 F tetrahedra. beo4 170-174 ATP binding cassette subfamily A member 12 Homo sapiens 51-54 30059171-4 2018 This creates a 1.5 microm thick protection layer composed of Ge, GeOx , Li2 CO3 , LiOH, LiCl, and Li2 O on Li surface that allows stable cycling of Li electrodes both in Li-symmetrical cells and Li-O2 cells, especially in "moist" electrolytes (with 1000-10 000 ppm H2 O) and humid O2 atmosphere (relative humidity (RH) of 45%). Oxygen 198-200 ATP binding cassette subfamily A member 12 Homo sapiens 72-75 29873130-3 2018 Another important problem is the deteriorating performance of Li-S batteries with prolonged cycling owing to irreversible deposition of lithium sulfide (Li2 S). Lithium 62-66 ATP binding cassette subfamily A member 12 Homo sapiens 153-156 29873130-3 2018 Another important problem is the deteriorating performance of Li-S batteries with prolonged cycling owing to irreversible deposition of lithium sulfide (Li2 S). lithium sulfide 136-151 ATP binding cassette subfamily A member 12 Homo sapiens 153-156 29873130-5 2018 Herein, porous molybdenum carbide nanorods (Mo2 C NRs), with high catalytic activity for Li2 S and ultrastrong adsorption for polysulfides, are used as a "bifunctional" host material and incorporated into sulfur cathodes for the first time. molybdenum carbide 15-33 ATP binding cassette subfamily A member 12 Homo sapiens 89-92 29873130-6 2018 The "bifunctional" Mo2 C NRs have the advantage of immobilizing polysulfides over the conventional host, with adsorption energies from -4.89 to -8.20 eV for Li2 Sx (x=1, 2, 4, 6, and 8). polysulfide 64-76 ATP binding cassette subfamily A member 12 Homo sapiens 157-160 29873130-8 2018 Therefore, the irreversible deposition of polysulfides is effectively restrained and the utilization of Li2 S is clearly enhanced. polysulfide 42-54 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 30203824-4 2018 The fracture-resistant size and ample contact with Super-P and Li2O greatly improved the electrochemical kinetics and cyclability to deliver a reversible capacity of 670 mA h g-1 after 700 cycles, which demonstrated the potential suitability of Mo-doped SnO2 nanoparticles as a long-cycle-life anode material. Tin(IV) oxide 254-258 ATP binding cassette subfamily A member 12 Homo sapiens 63-66 30059171-4 2018 This creates a 1.5 microm thick protection layer composed of Ge, GeOx , Li2 CO3 , LiOH, LiCl, and Li2 O on Li surface that allows stable cycling of Li electrodes both in Li-symmetrical cells and Li-O2 cells, especially in "moist" electrolytes (with 1000-10 000 ppm H2 O) and humid O2 atmosphere (relative humidity (RH) of 45%). Water 265-269 ATP binding cassette subfamily A member 12 Homo sapiens 72-75 30059171-4 2018 This creates a 1.5 microm thick protection layer composed of Ge, GeOx , Li2 CO3 , LiOH, LiCl, and Li2 O on Li surface that allows stable cycling of Li electrodes both in Li-symmetrical cells and Li-O2 cells, especially in "moist" electrolytes (with 1000-10 000 ppm H2 O) and humid O2 atmosphere (relative humidity (RH) of 45%). Oxygen 281-283 ATP binding cassette subfamily A member 12 Homo sapiens 72-75 30059171-4 2018 This creates a 1.5 microm thick protection layer composed of Ge, GeOx , Li2 CO3 , LiOH, LiCl, and Li2 O on Li surface that allows stable cycling of Li electrodes both in Li-symmetrical cells and Li-O2 cells, especially in "moist" electrolytes (with 1000-10 000 ppm H2 O) and humid O2 atmosphere (relative humidity (RH) of 45%). Rhodium 315-317 ATP binding cassette subfamily A member 12 Homo sapiens 72-75 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. tmtaah2 24-31 ATP binding cassette subfamily A member 12 Homo sapiens 12-22 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. tmtaah2 24-31 ATP binding cassette subfamily A member 12 Homo sapiens 16-21 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. dibenzotetramethyltetraaza[14]annulene 34-72 ATP binding cassette subfamily A member 12 Homo sapiens 12-22 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. dibenzotetramethyltetraaza[14]annulene 34-72 ATP binding cassette subfamily A member 12 Homo sapiens 16-21 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. dibenzotetramethyltetraaza[14]annulene 34-72 ATP binding cassette subfamily A member 12 Homo sapiens 24-29 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. uo2cl2(thf)3 91-103 ATP binding cassette subfamily A member 12 Homo sapiens 12-22 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. uo2cl2(thf)3 91-103 ATP binding cassette subfamily A member 12 Homo sapiens 16-21 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. uo2cl2(thf)3 91-103 ATP binding cassette subfamily A member 12 Homo sapiens 24-29 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. bis(uranyl) complex 158-177 ATP binding cassette subfamily A member 12 Homo sapiens 12-22 29939730-1 2018 Reaction of Li2(tmtaa) (tmtaaH2 = dibenzotetramethyltetraaza[14]annulene) with 1 equiv of [UO2Cl2(THF)3], in an attempt to form cis-[UO2(tmtaa)], affords the bis(uranyl) complex [Li(THF)3][Li(THF)2][(UO2Cl2)2(tmtaa)] (1) as a red-brown crystalline solid in modest yield. bis(uranyl) complex 158-177 ATP binding cassette subfamily A member 12 Homo sapiens 16-21 29939730-2 2018 Complex 1 can be synthesized rationally by reaction of Li2(tmtaa) with 2 equiv of [UO2Cl2(THF)3]. [uo2cl2(thf)3 82-95 ATP binding cassette subfamily A member 12 Homo sapiens 55-65 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. dimethylethylsilylimidazole 55-58 ATP binding cassette subfamily A member 12 Homo sapiens 19-29 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. dimethylethylsilylimidazole 55-58 ATP binding cassette subfamily A member 12 Homo sapiens 23-28 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. dimethylethylsilylimidazole 55-58 ATP binding cassette subfamily A member 12 Homo sapiens 62-67 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. [uo2cl2(thf)3 83-96 ATP binding cassette subfamily A member 12 Homo sapiens 19-29 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. [uo2cl2(thf)3 83-96 ATP binding cassette subfamily A member 12 Homo sapiens 23-28 29939730-8 2018 In contrast to the Li2(tmtaa) reaction, addition of [K(DME)]2[tmtaa] to 1 equiv of [UO2Cl2(THF)3] results in formation of the 2e- oxidation products of (tmtaa)2-. [uo2cl2(thf)3 83-96 ATP binding cassette subfamily A member 12 Homo sapiens 62-67 29939730-11 2018 We hypothesize that these ligand oxidation products are formed upon decomposition of the unobserved cis uranyl intermediate, cis-[UO2(tmtaa)], which undergoes a facile intramolecular redox reaction. cis uranyl 100-110 ATP binding cassette subfamily A member 12 Homo sapiens 134-139 29939730-11 2018 We hypothesize that these ligand oxidation products are formed upon decomposition of the unobserved cis uranyl intermediate, cis-[UO2(tmtaa)], which undergoes a facile intramolecular redox reaction. cis-[uo2 125-133 ATP binding cassette subfamily A member 12 Homo sapiens 134-139 29215768-0 2018 From a Metastable Layer to a Stable Ring: A Kinetic Study for Transformation Reactions of Li2 Mo3 TeO12 to Polyoxometalates. polyoxometalate I 107-123 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 30068157-6 2018 A large search over possible contraction schemes is done for the Li2 and Na2 molecules, and based on this search contracted pcJ-n basis sets for the four atoms are recommended. pcj 124-127 ATP binding cassette subfamily A member 12 Homo sapiens 65-68 30068157-6 2018 A large search over possible contraction schemes is done for the Li2 and Na2 molecules, and based on this search contracted pcJ-n basis sets for the four atoms are recommended. Nitrogen 31-32 ATP binding cassette subfamily A member 12 Homo sapiens 65-68 29533492-1 2018 The synthesis and identification of unprecedented gem-dianionic phosphorus compounds, that is, gem-dilithium phosphido-boranes Li2 [RP BH3 ], with R=Ph or Cy, are reported in THF solution. gem-dianionic phosphorus 50-74 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 29533492-1 2018 The synthesis and identification of unprecedented gem-dianionic phosphorus compounds, that is, gem-dilithium phosphido-boranes Li2 [RP BH3 ], with R=Ph or Cy, are reported in THF solution. gem-dilithium phosphido-boranes 95-126 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 29533492-1 2018 The synthesis and identification of unprecedented gem-dianionic phosphorus compounds, that is, gem-dilithium phosphido-boranes Li2 [RP BH3 ], with R=Ph or Cy, are reported in THF solution. BH 3 135-138 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 29533492-1 2018 The synthesis and identification of unprecedented gem-dianionic phosphorus compounds, that is, gem-dilithium phosphido-boranes Li2 [RP BH3 ], with R=Ph or Cy, are reported in THF solution. Cysteine 155-157 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 29533492-1 2018 The synthesis and identification of unprecedented gem-dianionic phosphorus compounds, that is, gem-dilithium phosphido-boranes Li2 [RP BH3 ], with R=Ph or Cy, are reported in THF solution. tetrahydrofuran 175-178 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 29950672-5 2018 Additionally, oxygen contamination within the Li2S-P2S5 leads initially to Li3PO4 phase segregation, and subsequently to Li2O formation. Oxygen 14-20 ATP binding cassette subfamily A member 12 Homo sapiens 46-49 29950672-5 2018 Additionally, oxygen contamination within the Li2S-P2S5 leads initially to Li3PO4 phase segregation, and subsequently to Li2O formation. Lithium phosphate 75-81 ATP binding cassette subfamily A member 12 Homo sapiens 46-49 29215768-1 2018 A metastable tellurite, Li2 Mo3 TeO12 , revealing a corrugated layered structure in an extremely strained coordination environment was hydrothermally synthesized in high yield. tellurous acid 13-22 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 29215768-1 2018 A metastable tellurite, Li2 Mo3 TeO12 , revealing a corrugated layered structure in an extremely strained coordination environment was hydrothermally synthesized in high yield. teo12 32-37 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 29243342-3 2018 The discovery of Li2 CO3 as the main discharge product in carbonate-based electrolytes once brought researchers to "the end of the idyll" in the early 2010s. Carbonates 58-67 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 29388730-1 2018 The reaction of the allene precursor Li2 (Me3 SiC3 SiMe3 ) with [Cp2 ZrCl2 ] (Cp=cyclopentadienyl) was examined. propadiene 20-26 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 29388730-1 2018 The reaction of the allene precursor Li2 (Me3 SiC3 SiMe3 ) with [Cp2 ZrCl2 ] (Cp=cyclopentadienyl) was examined. bis(cyclopentadienyl)magnesium 81-97 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 29388730-3 2018 Upon sigma coordination of the allenediyl unit to {Cp2 Zr}, pyrophoric Li2 (Me3 SiC3 SiMe3 ) is tamed stepwise to yield a surprisingly robust 1,5-dizirconacyclooctatetra-2,3,6,7-ene with cumulated double bonds. allenediyl 31-41 ATP binding cassette subfamily A member 12 Homo sapiens 71-74 29388730-3 2018 Upon sigma coordination of the allenediyl unit to {Cp2 Zr}, pyrophoric Li2 (Me3 SiC3 SiMe3 ) is tamed stepwise to yield a surprisingly robust 1,5-dizirconacyclooctatetra-2,3,6,7-ene with cumulated double bonds. 1,5-dizirconacyclooctatetra-2,3,6,7-ene 142-181 ATP binding cassette subfamily A member 12 Homo sapiens 71-74 29024174-0 2018 Li2 NH-LiBH4 : a Complex Hydride with Near Ambient Hydrogen Adsorption and Fast Lithium Ion Conduction. Hydrogen 51-59 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 29446430-3 2018 It is found that the as-synthesized 80 nm-sized SnO2-Fe2O3-C hollow sphere electrode exhibits an extraordinary reversible capacity (1100 mA h g-1 after 100 cycles at 200 mA g-1) and excellent long cycle stability (475 mA h g-1 after 1000 cycles at 2000 mA g-1), which are attributed to the Fe-enhanced reversibility of the Li2O reduction reaction, high electrical conductivity, high Li+ ion mobility, and structural stability of the carbon-coated triple-shell hollow spheres. Tin(IV) oxide 48-52 ATP binding cassette subfamily A member 12 Homo sapiens 323-326 29446430-3 2018 It is found that the as-synthesized 80 nm-sized SnO2-Fe2O3-C hollow sphere electrode exhibits an extraordinary reversible capacity (1100 mA h g-1 after 100 cycles at 200 mA g-1) and excellent long cycle stability (475 mA h g-1 after 1000 cycles at 2000 mA g-1), which are attributed to the Fe-enhanced reversibility of the Li2O reduction reaction, high electrical conductivity, high Li+ ion mobility, and structural stability of the carbon-coated triple-shell hollow spheres. Iron 53-55 ATP binding cassette subfamily A member 12 Homo sapiens 323-326 29532965-2 2018 The anionic oxygen redox induced by activation of the Li2 MnO3 domain has previously afforded an O3-type layered Li-rich material used as the cathode for lithium-ion batteries with a notably high capacity of 250-300 mAh g-1 . Oxygen 12-18 ATP binding cassette subfamily A member 12 Homo sapiens 54-57 29532965-2 2018 The anionic oxygen redox induced by activation of the Li2 MnO3 domain has previously afforded an O3-type layered Li-rich material used as the cathode for lithium-ion batteries with a notably high capacity of 250-300 mAh g-1 . Lithium 154-161 ATP binding cassette subfamily A member 12 Homo sapiens 54-57 29532965-5 2018 The activation of a single-layer Li2 MnO3 enables stable anionic oxygen redox reactions and leads to a highly reversible charge-discharge cycle. Oxygen 65-71 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 29292844-5 2018 Moreover, the presence of MXene leads to enhanced Li and Li2 S adsorption during the intercalation and conversion reactions. mxene 26-31 ATP binding cassette subfamily A member 12 Homo sapiens 57-60 29024174-0 2018 Li2 NH-LiBH4 : a Complex Hydride with Near Ambient Hydrogen Adsorption and Fast Lithium Ion Conduction. Lithium 80-87 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 29024174-2 2018 Here a complex hydride made of Li2 NH and LiBH4 was synthesized, which has a structure tentatively indexed using an orthorhombic cell with a space group of Pna21 and lattice parameters of a=10.121, b=6.997, and c=11.457 A. Creatinine 15-22 ATP binding cassette subfamily A member 12 Homo sapiens 31-34 29024174-3 2018 The Li2 NH-LiBH4 sample (in a molar ratio of 1:1) shows excellent hydrogenation kinetics, starting to absorb H2 at 310 K, which is more than 100 K lower than that of pristine Li2 NH. Hydrogen 109-111 ATP binding cassette subfamily A member 12 Homo sapiens 4-7 29024174-3 2018 The Li2 NH-LiBH4 sample (in a molar ratio of 1:1) shows excellent hydrogenation kinetics, starting to absorb H2 at 310 K, which is more than 100 K lower than that of pristine Li2 NH. Hydrogen 109-111 ATP binding cassette subfamily A member 12 Homo sapiens 175-178 29024174-4 2018 Furthermore, the Li+ ion conductivity of the Li2 NH-LiBH4 sample is about 1.0x10-5 S cm-1 at room temperature, and is higher than that of either Li2 NH or LiBH4 at 373 K. Those unique properties of the Li2 NH-LiBH4 complex render it a promising candidate for hydrogen storage and Li ion conduction. LiBH4 52-57 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 29024174-4 2018 Furthermore, the Li+ ion conductivity of the Li2 NH-LiBH4 sample is about 1.0x10-5 S cm-1 at room temperature, and is higher than that of either Li2 NH or LiBH4 at 373 K. Those unique properties of the Li2 NH-LiBH4 complex render it a promising candidate for hydrogen storage and Li ion conduction. Hydrogen 260-268 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 28986970-1 2017 A new selenide with a diamond-like structure, Li2 MnSnSe4 , was synthesized for the first time by using a conventional high-temperature solid-state reaction method. Selenium 6-14 ATP binding cassette subfamily A member 12 Homo sapiens 46-49 29210479-4 2018 An interconnected framework of ultrathin metallic copper formed provides a high conductivity backbone and cohesive support to accommodate the volume change and has a cube-on-cube orientation relationship with Li2 O. Copper 50-56 ATP binding cassette subfamily A member 12 Homo sapiens 209-212 29083913-1 2017 The layered lithium nitridonickelate Li2.0(1)Ni0.67(2)N has been investigated as a negative electrode in the 0.02-1.25 V vs Li+/Li potential window. lithium nitridonickelate 12-36 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 29083913-7 2017 As a consequence, a high capacity of 200 mAh g-1 at C/10 is obtained with an excellent capacity retention, close to 100% even after 100 cycles, which makes Li2.0(1)Ni0.67(2)N a promising negative electrode material for Li-ion batteries. CHEMBL2180945 164-167 ATP binding cassette subfamily A member 12 Homo sapiens 156-159 28653777-4 2017 Due to the enhanced electrical conductivity and noticeable blocking effect for the shuttle of polysulfides, the binder-free flexible VG/Li2 S-C cathode exhibits high rate performance and reinforced cycles (656.2 mAh g-1 after 100 cycles). polysulfide 94-106 ATP binding cassette subfamily A member 12 Homo sapiens 136-139 28640435-4 2017 It is found that the Sn C bond can act as an ultrafast electron transfer path, facilitating the reversible conversion reaction between Sn and Li2 O to form SnO2 . Tin 21-23 ATP binding cassette subfamily A member 12 Homo sapiens 142-145 28295493-4 2017 Next-generation sequencing identified novel mutations of the ATP-binding cassette subfamily A member 12 gene (ABCA12), c.5884+4_+5delAA and c.7239G>A, which caused skipping of exons 39 and 48, respectively. Adenosine Triphosphate 61-64 ATP binding cassette subfamily A member 12 Homo sapiens 110-116 28653777-0 2017 Vertical-Aligned Li2 S-Graphene Encapsulated within a Carbon Shell as a Free-Standing Cathode for Lithium-Sulfur Batteries. Carbon 54-60 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 28653777-0 2017 Vertical-Aligned Li2 S-Graphene Encapsulated within a Carbon Shell as a Free-Standing Cathode for Lithium-Sulfur Batteries. Lithium 98-105 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 28653777-0 2017 Vertical-Aligned Li2 S-Graphene Encapsulated within a Carbon Shell as a Free-Standing Cathode for Lithium-Sulfur Batteries. Sulfur 106-112 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 28653777-2 2017 In this work, we have developed a double-modification strategy to integrate lithium sulfide (Li2 S) into a conductive composite network consisting of vertical graphene (VG) arrays and an amorphous carbon shell, forming an integrated cathode (VG/Li2 S-C). lithium sulfide 76-91 ATP binding cassette subfamily A member 12 Homo sapiens 93-96 28653777-2 2017 In this work, we have developed a double-modification strategy to integrate lithium sulfide (Li2 S) into a conductive composite network consisting of vertical graphene (VG) arrays and an amorphous carbon shell, forming an integrated cathode (VG/Li2 S-C). Graphite 159-167 ATP binding cassette subfamily A member 12 Homo sapiens 93-96 28653777-2 2017 In this work, we have developed a double-modification strategy to integrate lithium sulfide (Li2 S) into a conductive composite network consisting of vertical graphene (VG) arrays and an amorphous carbon shell, forming an integrated cathode (VG/Li2 S-C). Carbon 197-203 ATP binding cassette subfamily A member 12 Homo sapiens 93-96 28640435-4 2017 It is found that the Sn C bond can act as an ultrafast electron transfer path, facilitating the reversible conversion reaction between Sn and Li2 O to form SnO2 . Tin(IV) oxide 156-160 ATP binding cassette subfamily A member 12 Homo sapiens 142-145 28429506-3 2017 Such fine Sn precipitates and their ample contact with Li2 O proliferate the reversible Sn Li x Sn Sn SnO2 /SnO2-x cycle during charging/discharging. Tin(IV) oxide 108-112 ATP binding cassette subfamily A member 12 Homo sapiens 55-58 28296133-6 2017 The issue of large voltage hysteresis upon conversion/de-conversion is circumvented by operating iron oxide in a deeply lithiated Fe/Li2 O form. ferric oxide 97-107 ATP binding cassette subfamily A member 12 Homo sapiens 133-136 28504885-5 2017 Reaction of [UO2(N(SiMe3)2)2(THF)2] with 1 equiv of Li2(tmtaa) in C6H6 results in the formation of [Li(THF)]2[UO2(N(SiMe3)2)2(tmtaa)] (3), which can be isolated in 55% yield as a red-brown crystalline solid. uo2(n(sime3)2)2(thf)2 13-34 ATP binding cassette subfamily A member 12 Homo sapiens 52-70 28504885-5 2017 Reaction of [UO2(N(SiMe3)2)2(THF)2] with 1 equiv of Li2(tmtaa) in C6H6 results in the formation of [Li(THF)]2[UO2(N(SiMe3)2)2(tmtaa)] (3), which can be isolated in 55% yield as a red-brown crystalline solid. [li(thf)]2[uo2(n(sime3)2)2(tmtaa)] (3) 99-137 ATP binding cassette subfamily A member 12 Homo sapiens 52-70 28596568-0 2017 Influence of rovibrational excitation on the non-diabatic state-to-state dynamics for the Li(2p) + H2 LiH + H reaction. Hydrogen 99-101 ATP binding cassette subfamily A member 12 Homo sapiens 90-95 28596568-0 2017 Influence of rovibrational excitation on the non-diabatic state-to-state dynamics for the Li(2p) + H2 LiH + H reaction. Lithium 104-107 ATP binding cassette subfamily A member 12 Homo sapiens 90-95 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 93-96 ATP binding cassette subfamily A member 12 Homo sapiens 105-110 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 93-96 ATP binding cassette subfamily A member 12 Homo sapiens 231-236 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Hydrogen 114-116 ATP binding cassette subfamily A member 12 Homo sapiens 105-110 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Hydrogen 114-116 ATP binding cassette subfamily A member 12 Homo sapiens 231-236 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 105-110 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 231-236 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 105-110 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 231-236 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 105-110 28596568-5 2017 With the increase of the collision energy, the sideways and backward scattered tendencies of LiH for the Li(2p) + H2(v = 0, j = 0, 1) LiH + H reactions are enhanced slightly, while the backward scattering tendency of LiH for the Li(2p) + H2(v = 1, j = 0) LiH + H reaction becomes remarkably weakened. Lithium 136-139 ATP binding cassette subfamily A member 12 Homo sapiens 231-236 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. Carbon 35-41 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. birnessite 64-74 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. manganese oxide 80-95 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. manganese dioxide 108-112 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. Hexachlorobenzene 114-117 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28371370-3 2017 A rational nanostructure of hollow carbon nanoboxes filled with birnessite-type manganese oxide nanosheets (MnO2 @HCB) as a new class of molecularly-designed physical and chemical trap for lithium polysulfides (Li2 Sx (x = 4-8)) is reported. lithium polysulfides 189-209 ATP binding cassette subfamily A member 12 Homo sapiens 211-214 28244150-4 2017 The Ag2 Mo2 O7 electrode is likely to be decomposed into amorphous molybdenum, Li2 O, and metallic silver based on the conversion reaction. Molybdenum, ion(Mo2 ) 8-11 ATP binding cassette subfamily A member 12 Homo sapiens 79-82 28247542-0 2017 Towards an Understanding of Li2 O2 Evolution in Li-O2 Batteries: An In Operando Synchrotron X-ray Diffraction Study. Oxygen 32-34 ATP binding cassette subfamily A member 12 Homo sapiens 28-31 28247542-1 2017 One of the major challenges in developing high-performance Li-O2 batteries is to understand the Li2 O2 formation and decomposition during battery cycling. li-o2 59-64 ATP binding cassette subfamily A member 12 Homo sapiens 96-99 28247542-4 2017 By quantitatively tracking Li2 O2 during discharge and charge, a two-step process was suggested for both growth and oxidation of Li2 O2 owing to different mechanisms during two stages of both oxygen reduction reaction and oxygen evolution reaction. Oxygen 192-198 ATP binding cassette subfamily A member 12 Homo sapiens 27-30 28247542-4 2017 By quantitatively tracking Li2 O2 during discharge and charge, a two-step process was suggested for both growth and oxidation of Li2 O2 owing to different mechanisms during two stages of both oxygen reduction reaction and oxygen evolution reaction. Oxygen 192-198 ATP binding cassette subfamily A member 12 Homo sapiens 129-132 28247542-4 2017 By quantitatively tracking Li2 O2 during discharge and charge, a two-step process was suggested for both growth and oxidation of Li2 O2 owing to different mechanisms during two stages of both oxygen reduction reaction and oxygen evolution reaction. Oxygen 222-228 ATP binding cassette subfamily A member 12 Homo sapiens 27-30 28247542-4 2017 By quantitatively tracking Li2 O2 during discharge and charge, a two-step process was suggested for both growth and oxidation of Li2 O2 owing to different mechanisms during two stages of both oxygen reduction reaction and oxygen evolution reaction. Oxygen 222-228 ATP binding cassette subfamily A member 12 Homo sapiens 129-132 28247542-6 2017 These grains can stack together so that they facilitate the nucleation and growth of toroidal Li2 O2 particles with a LiO2 -like surface, which could cause parasitic reactions and hinder the formation of Li2 O2 . lio2 118-122 ATP binding cassette subfamily A member 12 Homo sapiens 94-97 28247542-6 2017 These grains can stack together so that they facilitate the nucleation and growth of toroidal Li2 O2 particles with a LiO2 -like surface, which could cause parasitic reactions and hinder the formation of Li2 O2 . lio2 118-122 ATP binding cassette subfamily A member 12 Homo sapiens 204-207 27991678-6 2017 Based on thermodynamic analysis, Li[Be(NH2 BH3 )3 ] and Li2 [Be(NH2 BH3 )4 ] are the most perspective synthetic targets. be(nh2 bh3 )4 61-74 ATP binding cassette subfamily A member 12 Homo sapiens 56-59 27532334-6 2016 The energy profiles of (Li2O2)2 and (Li2O)2 nucleation on delta-MnO2 monolayer during the discharge process demonstrate that Li2O2 is the predominant discharge product and that further reduction to Li2O is inhibited by the high overpotential of 1.21 V. Interface structures have been examined to study the interaction between the Li2O2 and MnO2 layers. delta-mno2 58-68 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 28098421-0 2017 Hexagonal Boron Nitride (h-BN) Sheets Decorated with OLi, ONa, and Li2 F Molecules for Enhanced Energy Storage. boron nitride 10-23 ATP binding cassette subfamily A member 12 Homo sapiens 67-70 28098421-1 2017 First-principles electronic structure calculations were carried out on hexagonal boron nitride (h-BN) sheets functionalized with small molecules, such as OLi, ONa, and Li2 F, to study their hydrogen (H2 ) storage properties. boron nitride 96-100 ATP binding cassette subfamily A member 12 Homo sapiens 168-171 28134456-0 2017 Sulfiphilic Nickel Phosphosulfide Enabled Li2 S Impregnation in 3D Graphene Cages for Li-S Batteries. nickel phosphosulfide 12-33 ATP binding cassette subfamily A member 12 Homo sapiens 42-45 28134456-0 2017 Sulfiphilic Nickel Phosphosulfide Enabled Li2 S Impregnation in 3D Graphene Cages for Li-S Batteries. Graphite 67-75 ATP binding cassette subfamily A member 12 Homo sapiens 42-45 28134456-0 2017 Sulfiphilic Nickel Phosphosulfide Enabled Li2 S Impregnation in 3D Graphene Cages for Li-S Batteries. Lithium 86-90 ATP binding cassette subfamily A member 12 Homo sapiens 42-45 32009741-1 2017 Abstract: This work reports the synthesis of lithium-silicate glass, containing 10 mol% of Li 2 O by the sol-gel process, intended for the regeneration of cartilage. aluminum lithium silicate 45-61 ATP binding cassette subfamily A member 12 Homo sapiens 91-96 27786395-0 2016 Lithium Ion Mobility in Lithium Phosphidosilicates: Crystal Structure, 7 Li, 29 Si, and 31 P MAS NMR Spectroscopy, and Impedance Spectroscopy of Li8 SiP4 and Li2 SiP2. Lithium 0-7 ATP binding cassette subfamily A member 12 Homo sapiens 158-161 27786395-2 2016 The study of the ternary system Li-Si-P revealed a series of new compounds, two of which, Li8 SiP4 and Li2 SiP2 , are presented. si-p 35-39 ATP binding cassette subfamily A member 12 Homo sapiens 103-106 27532334-6 2016 The energy profiles of (Li2O2)2 and (Li2O)2 nucleation on delta-MnO2 monolayer during the discharge process demonstrate that Li2O2 is the predominant discharge product and that further reduction to Li2O is inhibited by the high overpotential of 1.21 V. Interface structures have been examined to study the interaction between the Li2O2 and MnO2 layers. Li2O2 125-130 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 27532334-6 2016 The energy profiles of (Li2O2)2 and (Li2O)2 nucleation on delta-MnO2 monolayer during the discharge process demonstrate that Li2O2 is the predominant discharge product and that further reduction to Li2O is inhibited by the high overpotential of 1.21 V. Interface structures have been examined to study the interaction between the Li2O2 and MnO2 layers. manganese dioxide 64-68 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 27448886-1 2016 The potential energy surfaces of the ground and low-lying excited states for the insertion reaction of atomic fluorine (F) and fluoride (F(-)) into the dilithium (Li2) molecule have been investigated. Fluorides 127-135 ATP binding cassette subfamily A member 12 Homo sapiens 163-166 27448886-1 2016 The potential energy surfaces of the ground and low-lying excited states for the insertion reaction of atomic fluorine (F) and fluoride (F(-)) into the dilithium (Li2) molecule have been investigated. Lithium dimer 152-161 ATP binding cassette subfamily A member 12 Homo sapiens 163-166 27347697-2 2016 Paired with a metallic lithium anode, the Sex chains are converted to Li2Se in a single-step reaction. Lithium 23-30 ATP binding cassette subfamily A member 12 Homo sapiens 70-73 26794604-0 2016 Li2OHCl Crystalline Electrolyte for Stable Metallic Lithium Anodes. Lithium 52-59 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 26863512-7 2016 Those that move into the interlayer space form Li2 dimers with cations in the Li2N layers and those that move into the neighboring layer form dimers with cations therein. li2n 78-82 ATP binding cassette subfamily A member 12 Homo sapiens 47-50 26794604-1 2016 In a classic example of stability from instability, we show that Li2OHCl solid electrolyte forms a stable solid electrolyte interphase (SEI) layer with a metallic lithium anode. Lithium 163-170 ATP binding cassette subfamily A member 12 Homo sapiens 65-68 24850635-1 2015 A series of single-phase full-color emitting Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) phosphors were synthesized by solid-state reaction and characterized by X-ray diffraction and photoluminescence analyses. sio4 57-61 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 25950203-0 2015 Dissociative Photoionization of He Li2: A Theoretical Study. Helium 32-34 ATP binding cassette subfamily A member 12 Homo sapiens 37-40 25950203-1 2015 Dissociative photoionization of the He Li2 van der Waals complex to the ground electronic state of the He Li2+ ion is investigated theoretically. Helium 36-38 ATP binding cassette subfamily A member 12 Homo sapiens 41-44 25950203-1 2015 Dissociative photoionization of the He Li2 van der Waals complex to the ground electronic state of the He Li2+ ion is investigated theoretically. Helium 36-38 ATP binding cassette subfamily A member 12 Homo sapiens 110-113 26130378-3 2015 Upon further lithiation, LiRuO2 formed by intercalation decomposes to nanosized Ru metal and Li2 O by a conversion reaction. liruo2 25-31 ATP binding cassette subfamily A member 12 Homo sapiens 93-96 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). cis-5 9-14 ATP binding cassette subfamily A member 12 Homo sapiens 82-85 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). cis-5 9-14 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). lithium aluminum hydride 45-53 ATP binding cassette subfamily A member 12 Homo sapiens 82-85 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). lithium aluminum hydride 45-53 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). tetrahydrofuran 57-60 ATP binding cassette subfamily A member 12 Homo sapiens 82-85 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). tetrahydrofuran 57-60 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). diborate 73-81 ATP binding cassette subfamily A member 12 Homo sapiens 82-85 25892077-3 2015 Compound cis-5, in turn, can be reduced with Li[AlH4] in THF to give its diborate Li2[cis-9,10-(BH3)2-DHA] (Li2 [cis-6]). diborate 73-81 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 25892077-4 2015 In the crystal lattice, the THF solvate Li2[cis-6] 3 THF establishes a dimeric structure with Li-(mu-H)-B coordination modes. tetrahydrofuran 28-31 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 25892077-5 2015 Hydride abstraction from Li2[cis-6] with Me3SiCl yields the B-H-B-bridged DHA Li[7]. dha li 74-80 ATP binding cassette subfamily A member 12 Homo sapiens 25-28 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. cis-6 17-22 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. trimethylsilyl trifluoromethanesulfonate 68-76 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. trifluoromethanesulfonic acid 85-114 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. tetrahydrofuran 119-122 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. tetrahydrofuran 135-138 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 25892077-7 2015 Treatment of Li2[cis-6] with the stronger hydride abstracting agent Me3SiOTf (HOTf = trifluoromethanesulfonic acid) in THF affords the THF diadduct of cis-9,10-(BH(OTf))2-DHA. cis-9,10-(bh(otf))2-dha 151-174 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 26836249-0 2016 Li2S Film Formation on Lithium Anode Surface of Li-S batteries. Lithium 23-30 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 26836249-0 2016 Li2S Film Formation on Lithium Anode Surface of Li-S batteries. li-s 48-52 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 26473399-4 2015 As revealed by nanoscale imaging, diffraction, and spectroscopy, it is shown that the rapid and deep lithiation of WO3 nanowires leads to the formation of highly disordered and near-amorphous Lix WO3 phases, but with no detectable traces of elemental W and segregated Li2 O phase formation. Tungsten 115-116 ATP binding cassette subfamily A member 12 Homo sapiens 268-271 26257297-1 2015 The kinetics of Li2 S electrodeposition onto carbon in lithium-sulfur batteries are characterized. Carbon 45-51 ATP binding cassette subfamily A member 12 Homo sapiens 16-19 26257297-1 2015 The kinetics of Li2 S electrodeposition onto carbon in lithium-sulfur batteries are characterized. Lithium 55-62 ATP binding cassette subfamily A member 12 Homo sapiens 16-19 26257297-1 2015 The kinetics of Li2 S electrodeposition onto carbon in lithium-sulfur batteries are characterized. Sulfur 63-69 ATP binding cassette subfamily A member 12 Homo sapiens 16-19 25620728-2 2015 The Li-storage mechanism of these oxides is suggested to involve an unusual conversion reaction leading to the formation of metallic nanograins and Li2 O; however, a full-scale conversion reaction is seldom observed in molybdenum dioxide (MoO2 ) at room temperature due to slow kinetics. Oxides 34-40 ATP binding cassette subfamily A member 12 Homo sapiens 148-151 25651930-7 2015 In addition, oat oil treatment increased both receptor expression and, consistent with the literature on PPARs, oat oil treatment resulted in a significant upregulation of differentiation genes (involucrin, SPRRs and transglutaminase 1) and ceramide processing genes (beta-glucocerebrosidase, sphingomyelinases 3 and ABCA12). oat oil 13-20 ATP binding cassette subfamily A member 12 Homo sapiens 317-323 25651930-7 2015 In addition, oat oil treatment increased both receptor expression and, consistent with the literature on PPARs, oat oil treatment resulted in a significant upregulation of differentiation genes (involucrin, SPRRs and transglutaminase 1) and ceramide processing genes (beta-glucocerebrosidase, sphingomyelinases 3 and ABCA12). oat oil 112-119 ATP binding cassette subfamily A member 12 Homo sapiens 317-323 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. ternary nitride 108-123 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. litmn 127-132 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. Hydrogen 137-139 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. litmn 167-172 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. Thulium 94-96 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 25604896-3 2015 The catalysis is fulfilled via the two-step cycle comprising: 1) the reaction of Li2NH and 3d TM(N) to form ternary nitride of LiTMN and H2, and 2) the ammoniation of LiTMN to Li2NH, TM(N) and N2 resulting in the neat reaction of 2 NH3 N2+3 H2. Nitrogen 193-195 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 24850635-5 2015 By manipulating Eu(3+) and Dy(3+) concentrations, the color points of Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) were tuned from the greenish-white region to white light and eventually to reddish-white region, demonstrating that a tunable white light can be obtained by Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) phosphors. sio4 82-86 ATP binding cassette subfamily A member 12 Homo sapiens 70-73 24850635-5 2015 By manipulating Eu(3+) and Dy(3+) concentrations, the color points of Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) were tuned from the greenish-white region to white light and eventually to reddish-white region, demonstrating that a tunable white light can be obtained by Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) phosphors. sio4 82-86 ATP binding cassette subfamily A member 12 Homo sapiens 262-265 24850635-5 2015 By manipulating Eu(3+) and Dy(3+) concentrations, the color points of Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) were tuned from the greenish-white region to white light and eventually to reddish-white region, demonstrating that a tunable white light can be obtained by Li2 Sr1-x-y SiO4 :xDy(3+) ,yEu(3+) phosphors. sio4 274-278 ATP binding cassette subfamily A member 12 Homo sapiens 70-73 24850635-6 2015 Li2 Sr0.98-x SiO4 :0.02Dy(3+) , xEu(3+) can serve as a white-light-emitting phosphor for phosphor-converted light-emitting diode. sio4 13-17 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 25130188-3 2014 As a result, one idling Li2O equivalent is generated from Li2MO3. li2mo3 58-64 ATP binding cassette subfamily A member 12 Homo sapiens 24-27 25356533-3 2014 When [OMIm]Tf2N is evaporated on top of a thin lithium film a chemical shift analysis of XPS spectra shows a variety of reaction products like LiF, Li2O and LixCHy which reveals the instability of the IL against lithium. Lithium 47-54 ATP binding cassette subfamily A member 12 Homo sapiens 148-151 25341076-7 2014 In the case of in situ charged bulk crystalline Li2O2, the Li vacancies preferentially form on the interlayer position (Li1), which is supported by first-principle calculations and consistent with their lower energy compared to those located next to oxygen (Li2). Oxygen 250-256 ATP binding cassette subfamily A member 12 Homo sapiens 48-51 22982209-6 2012 The mRNA levels of cholesterol transport regulators ABCA1 and ABCG1 were markedly downregulated by UVB, parallel to the lamellar ichthyosis related glucosylceramide transporter ABCA12 and the suspected sphingosine-1-phosphate and cholesterol sulfate transporter ABCC1. Cholesterol 19-30 ATP binding cassette subfamily A member 12 Homo sapiens 177-183 24764049-3 2014 The present perspective highlights the importance of assessing the electrochemical behaviour of Li2(Fe,Mn)SiO4 by combining an arsenal of characterization techniques both spectroscopic and structural, in and ex situ. Iron 100-102 ATP binding cassette subfamily A member 12 Homo sapiens 96-99 24764049-3 2014 The present perspective highlights the importance of assessing the electrochemical behaviour of Li2(Fe,Mn)SiO4 by combining an arsenal of characterization techniques both spectroscopic and structural, in and ex situ. sio4 106-110 ATP binding cassette subfamily A member 12 Homo sapiens 96-99 24580375-0 2014 Durable carbon-coated Li2(S) core-shell spheres for high performance lithium/sulfur cells. Carbon 8-14 ATP binding cassette subfamily A member 12 Homo sapiens 22-25 24580375-0 2014 Durable carbon-coated Li2(S) core-shell spheres for high performance lithium/sulfur cells. Lithium 69-76 ATP binding cassette subfamily A member 12 Homo sapiens 22-25 24580375-0 2014 Durable carbon-coated Li2(S) core-shell spheres for high performance lithium/sulfur cells. Sulfur 77-83 ATP binding cassette subfamily A member 12 Homo sapiens 22-25 24980144-5 2014 Among these, we rediscover known examples, where we actually identify the established functional SNP, and discover novel examples including the genes ABCA12, CALD1 and ZNF804, which we speculate may be linked to adaptations in skin, calcium metabolism and defense, respectively. znf804 168-174 ATP binding cassette subfamily A member 12 Homo sapiens 150-156 24980144-5 2014 Among these, we rediscover known examples, where we actually identify the established functional SNP, and discover novel examples including the genes ABCA12, CALD1 and ZNF804, which we speculate may be linked to adaptations in skin, calcium metabolism and defense, respectively. Calcium 233-240 ATP binding cassette subfamily A member 12 Homo sapiens 150-156 24722685-2 2014 It is found that Se is directly reduced to Li2Se in discharge without intermediate phases detected by in situ X-ray diffraction or X-ray absorption spectroscopy. Selenium 17-19 ATP binding cassette subfamily A member 12 Homo sapiens 43-46 23748698-5 2013 We show that Li2O2 is the only reversible discharge product in ether-based electrolyte solutions, and that the formation of Li2CO3, LiOH, or Li2O is either irreversible and/or reacts with the electrolyte solution or the carbon during its oxidation. Ether 63-68 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 22916963-0 2012 Synthesis, structure, and characterization of new Li+-d0-lone-pair-oxides: noncentrosymmetric polar Li6(Mo2O5)3(SeO3)6 and centrosymmetric Li2(MO3)(TeO3) (M = Mo6+ or W6+). Oxides 67-73 ATP binding cassette subfamily A member 12 Homo sapiens 139-142 22378617-0 2012 Li2 trapped inside tubiform [n] boron nitride clusters (n=4-8): structures and first hyperpolarizability. Nitrogen 28-31 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 22378617-0 2012 Li2 trapped inside tubiform [n] boron nitride clusters (n=4-8): structures and first hyperpolarizability. boron nitride 32-45 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 20496684-12 2010 The stronger IR peaks attributed to CO2 and formate species were observed, moreover there was still a weak IR peak assigned to carbonyl species for Cu1 Li1 Ce9Odelta catalyst when the temperature was above 180 degrees C. It was shown that as the electron donor, the doping of Li2 O on CuO-CeO2 catalyst could contribute to the irreversible desorption of CO at lower temperatures and inhibit the adsorption of H2 on the catalytic surface, and benefit the formation of formate species as well. cu1 li1 148-155 ATP binding cassette subfamily A member 12 Homo sapiens 276-279 21729033-0 2012 Novel adenosine triphosphate (ATP)-binding cassette, subfamily A, member 12 (ABCA12) mutations associated with congenital ichthyosiform erythroderma. Adenosine Triphosphate 6-28 ATP binding cassette subfamily A member 12 Homo sapiens 77-83 21729033-0 2012 Novel adenosine triphosphate (ATP)-binding cassette, subfamily A, member 12 (ABCA12) mutations associated with congenital ichthyosiform erythroderma. Adenosine Triphosphate 30-33 ATP binding cassette subfamily A member 12 Homo sapiens 77-83 22677707-7 2012 We found that the PPARalpha agonists clofibrate, docasohexaenoic acid, and WY-14,643 produced mild to moderate keratinocyte hyperplasia, increased stratification (particularly of granular and cornified layers), and enhanced levels of the differentiation markers filaggrin, ABCA12, and phosphorylated HSP27. Clofibrate 37-47 ATP binding cassette subfamily A member 12 Homo sapiens 273-279 22677707-7 2012 We found that the PPARalpha agonists clofibrate, docasohexaenoic acid, and WY-14,643 produced mild to moderate keratinocyte hyperplasia, increased stratification (particularly of granular and cornified layers), and enhanced levels of the differentiation markers filaggrin, ABCA12, and phosphorylated HSP27. docasohexaenoic acid 49-69 ATP binding cassette subfamily A member 12 Homo sapiens 273-279 22677707-7 2012 We found that the PPARalpha agonists clofibrate, docasohexaenoic acid, and WY-14,643 produced mild to moderate keratinocyte hyperplasia, increased stratification (particularly of granular and cornified layers), and enhanced levels of the differentiation markers filaggrin, ABCA12, and phosphorylated HSP27. tryptophyltyrosine 75-77 ATP binding cassette subfamily A member 12 Homo sapiens 273-279 21695021-10 2011 Recently, studies have shown that ceramides by increasing PPAR delta also increase the expression of ABCA12, which would facilitate the formation of lamellar bodies. Ceramides 34-43 ATP binding cassette subfamily A member 12 Homo sapiens 101-107 20545156-2 2010 The experimental results show that the UV-LIA coefficient change of LiNbO3 : Fe : Mn crystal is not large for congruent sample, increases with increasing Li2 O concentration, reaches the maximum 4. Iron 77-79 ATP binding cassette subfamily A member 12 Homo sapiens 154-157 20545156-6 2010 With the increase in Li2 O concentration in the LiNbO3 : Fe : Mn crystal, the amount of the bipolaron increases. Iron 57-59 ATP binding cassette subfamily A member 12 Homo sapiens 21-24 20545156-11 2010 The amount of bipolaron is the most with 49.57 mol% Li2 O concentration in the LiNbO3 : Fe : Mn crystal. Iron 88-90 ATP binding cassette subfamily A member 12 Homo sapiens 52-55 20496684-12 2010 The stronger IR peaks attributed to CO2 and formate species were observed, moreover there was still a weak IR peak assigned to carbonyl species for Cu1 Li1 Ce9Odelta catalyst when the temperature was above 180 degrees C. It was shown that as the electron donor, the doping of Li2 O on CuO-CeO2 catalyst could contribute to the irreversible desorption of CO at lower temperatures and inhibit the adsorption of H2 on the catalytic surface, and benefit the formation of formate species as well. ce9odelta 156-165 ATP binding cassette subfamily A member 12 Homo sapiens 276-279 18163683-0 2007 Collisional quenching of rotations in lithium dimers by ultracold helium: the Li2(a3Sigma u+) and Li2+(X2Sigma g+) targets. Helium 66-72 ATP binding cassette subfamily A member 12 Homo sapiens 78-81 19282840-6 2009 Furthermore, microarray analyses and quantitative PCR revealed that ER stress-inducing reagents, tunicamycin (TU), thapsigargin, and brefeldin A, altered the expression of genes essential for human epidermal KC differentiation, including C/EBPbeta, KLF4, and ABCA12 in vitro. Tunicamycin 97-108 ATP binding cassette subfamily A member 12 Homo sapiens 259-265 19282840-6 2009 Furthermore, microarray analyses and quantitative PCR revealed that ER stress-inducing reagents, tunicamycin (TU), thapsigargin, and brefeldin A, altered the expression of genes essential for human epidermal KC differentiation, including C/EBPbeta, KLF4, and ABCA12 in vitro. Tunicamycin 110-112 ATP binding cassette subfamily A member 12 Homo sapiens 259-265 19282840-6 2009 Furthermore, microarray analyses and quantitative PCR revealed that ER stress-inducing reagents, tunicamycin (TU), thapsigargin, and brefeldin A, altered the expression of genes essential for human epidermal KC differentiation, including C/EBPbeta, KLF4, and ABCA12 in vitro. Thapsigargin 115-127 ATP binding cassette subfamily A member 12 Homo sapiens 259-265 19282840-6 2009 Furthermore, microarray analyses and quantitative PCR revealed that ER stress-inducing reagents, tunicamycin (TU), thapsigargin, and brefeldin A, altered the expression of genes essential for human epidermal KC differentiation, including C/EBPbeta, KLF4, and ABCA12 in vitro. Brefeldin A 133-144 ATP binding cassette subfamily A member 12 Homo sapiens 259-265 19691382-7 2009 The large permanent dipole moment of CaF+ makes CaF qualitatively different from the other molecules in which the Stark effect in Rydberg states has been described (H2, Na2, Li2, NO, and H3) and makes it an ideal testbed for documenting the competition between the external and CaF+ dipole electric fields. caf+ 37-41 ATP binding cassette subfamily A member 12 Homo sapiens 174-177 19691382-7 2009 The large permanent dipole moment of CaF+ makes CaF qualitatively different from the other molecules in which the Stark effect in Rydberg states has been described (H2, Na2, Li2, NO, and H3) and makes it an ideal testbed for documenting the competition between the external and CaF+ dipole electric fields. cafestol palmitate 37-40 ATP binding cassette subfamily A member 12 Homo sapiens 174-177 19429679-0 2009 Ceramide stimulates ABCA12 expression via peroxisome proliferator-activated receptor {delta} in human keratinocytes. Ceramides 0-8 ATP binding cassette subfamily A member 12 Homo sapiens 20-26 19429679-1 2009 ABCA12 (ATP binding cassette transporter, family 12) is a cellular membrane transporter that facilitates the delivery of glucosylceramides to epidermal lamellar bodies in keratinocytes, a process that is critical for permeability barrier formation. Glucosylceramides 121-138 ATP binding cassette subfamily A member 12 Homo sapiens 0-6 19429679-5 2009 Here we demonstrate that ceramide (C(2)-Cer and C(6)-Cer), but not C(8)-glucosylceramides, sphingosine, or ceramide 1-phosphate, increases ABCA12 mRNA expression in a dose- and time-dependent manner. Ceramides 25-33 ATP binding cassette subfamily A member 12 Homo sapiens 139-145 19429679-5 2009 Here we demonstrate that ceramide (C(2)-Cer and C(6)-Cer), but not C(8)-glucosylceramides, sphingosine, or ceramide 1-phosphate, increases ABCA12 mRNA expression in a dose- and time-dependent manner. c(2)-cer 35-43 ATP binding cassette subfamily A member 12 Homo sapiens 139-145 19429679-5 2009 Here we demonstrate that ceramide (C(2)-Cer and C(6)-Cer), but not C(8)-glucosylceramides, sphingosine, or ceramide 1-phosphate, increases ABCA12 mRNA expression in a dose- and time-dependent manner. c(6)-cer 48-56 ATP binding cassette subfamily A member 12 Homo sapiens 139-145 19429679-7 2009 Moreover, simultaneous treatment with C(6)-Cer and each of these same inhibitors additively increased ABCA12 expression, indicating that ceramide is an important inducer of ABCA12 expression and that the conversion of ceramide to other sphingolipids or metabolites is not required. Ceramides 137-145 ATP binding cassette subfamily A member 12 Homo sapiens 102-108 19429679-7 2009 Moreover, simultaneous treatment with C(6)-Cer and each of these same inhibitors additively increased ABCA12 expression, indicating that ceramide is an important inducer of ABCA12 expression and that the conversion of ceramide to other sphingolipids or metabolites is not required. Ceramides 137-145 ATP binding cassette subfamily A member 12 Homo sapiens 173-179 19429679-7 2009 Moreover, simultaneous treatment with C(6)-Cer and each of these same inhibitors additively increased ABCA12 expression, indicating that ceramide is an important inducer of ABCA12 expression and that the conversion of ceramide to other sphingolipids or metabolites is not required. Ceramides 218-226 ATP binding cassette subfamily A member 12 Homo sapiens 102-108 19429679-8 2009 Finally, both exogenous and endogenous ceramides preferentially stimulate PPARdelta expression (but not other PPARs or liver X receptors), whereas PPARdelta knockdown by siRNA transfection specifically diminished the ceramide-induced increase in ABCA12 mRNA levels, indicating that PPARdelta is a mediator of the ceramide effect. Ceramides 217-225 ATP binding cassette subfamily A member 12 Homo sapiens 246-252 19429679-9 2009 Together, these results show that ceramide, an important lipid component of epidermis, up-regulates ABCA12 expression via the PPARdelta-mediated signaling pathway, providing a substrate-driven, feed-forward mechanism for regulating this key lipid transporter. Ceramides 34-42 ATP binding cassette subfamily A member 12 Homo sapiens 100-106 16902423-4 2006 Previously, we and others have shown that mutations in the ABCA12 gene encoding an adenosine triphosphate-binding cassette (ABC) transporter underlie the skin disease HI. Adenosine 83-92 ATP binding cassette subfamily A member 12 Homo sapiens 59-65 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. Germanium dichloride 13-18 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. 1,4-dioxane 19-26 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. tetraphenylporphine sulfonate 37-40 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. tetraphenylporphyrin 56-76 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. tetrahydrofuran 81-84 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. Germanium 13-15 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. tetraphenylporphine sulfonate 50-53 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 17550248-1 2007 Treatment of GeCl2(dioxane) with Li2(TPP)(OEt2)2 (TPP = tetraphenylporphyrin) in THF yields Ge(TPP), the first free Ge(II) porphyrin complex. Porphyrins 67-76 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 16003811-5 2005 A reverse structural change of complex 6 to LLB by the addition of one equivalent of Li2(binol) was also confirmed by ESI-MS and experimental results. BINOL, naphthol 89-94 ATP binding cassette subfamily A member 12 Homo sapiens 85-88 16676978-3 2006 The central metal ion has been demetalated and subsequently converted to the Li2 complex followed by conversion to the cobalt(II) complex. Metals 12-17 ATP binding cassette subfamily A member 12 Homo sapiens 77-80 16676978-3 2006 The central metal ion has been demetalated and subsequently converted to the Li2 complex followed by conversion to the cobalt(II) complex. Cobalt(2+) 119-129 ATP binding cassette subfamily A member 12 Homo sapiens 77-80 14615548-1 2003 We report on the Bose-Einstein condensation of more than 10(5) Li2 molecules in an optical trap starting from a spin mixture of fermionic lithium atoms. Lithium 138-145 ATP binding cassette subfamily A member 12 Homo sapiens 63-66 15651884-2 2005 It is shown that Li(2)Ga, a solid for which a Zintl-type electron-counting approach would suggest that a half-filled pi-type band occurs as in trans-polyacetylene, is really a three-dimensional solid with strong covalent interchain connections and small effective charge transfer. trans-polyacetylene 143-162 ATP binding cassette subfamily A member 12 Homo sapiens 17-24 15161308-7 2004 In tetrahydrofuran only N-metalated mixed LiCH(2)CN dimers were observed for both Li-1 and Li-2 with the less shielded (13)C NMR shifts of delta -2.5 and -2.2 for the alpha-carbon of LiCH(2)CN of the complexes. tetrahydrofuran 3-18 ATP binding cassette subfamily A member 12 Homo sapiens 91-95 15161308-7 2004 In tetrahydrofuran only N-metalated mixed LiCH(2)CN dimers were observed for both Li-1 and Li-2 with the less shielded (13)C NMR shifts of delta -2.5 and -2.2 for the alpha-carbon of LiCH(2)CN of the complexes. Nitrogen 24-25 ATP binding cassette subfamily A member 12 Homo sapiens 91-95 15161308-7 2004 In tetrahydrofuran only N-metalated mixed LiCH(2)CN dimers were observed for both Li-1 and Li-2 with the less shielded (13)C NMR shifts of delta -2.5 and -2.2 for the alpha-carbon of LiCH(2)CN of the complexes. Carbon 173-179 ATP binding cassette subfamily A member 12 Homo sapiens 91-95 12236748-6 2002 Time-dependent FTIR spectroscopy showed that Li2 undergoes carboxyl exchange with free carbon dioxide, with kinetics indicative of rate-limiting unimolecular dissociation of the N-CO(2) bond. Carbon Dioxide 87-101 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 12728548-4 2003 H2O, all compounds with integer lithium content exhibit good lithium ionic conductivity in their high temperature cubic phases above T = 33 degrees C. Lithium doping of samples LiX.H2O and Li2(OH)X leads to a suppression of the phase transition into the noncubic phases and the good ionic conductivity is extended down to lower temperatures (T < 0 degree C). Water 0-3 ATP binding cassette subfamily A member 12 Homo sapiens 189-192 12728548-4 2003 H2O, all compounds with integer lithium content exhibit good lithium ionic conductivity in their high temperature cubic phases above T = 33 degrees C. Lithium doping of samples LiX.H2O and Li2(OH)X leads to a suppression of the phase transition into the noncubic phases and the good ionic conductivity is extended down to lower temperatures (T < 0 degree C). Lithium 32-39 ATP binding cassette subfamily A member 12 Homo sapiens 189-192 12728548-4 2003 H2O, all compounds with integer lithium content exhibit good lithium ionic conductivity in their high temperature cubic phases above T = 33 degrees C. Lithium doping of samples LiX.H2O and Li2(OH)X leads to a suppression of the phase transition into the noncubic phases and the good ionic conductivity is extended down to lower temperatures (T < 0 degree C). Lithium 151-158 ATP binding cassette subfamily A member 12 Homo sapiens 189-192 14525314-1 2003 Previous work performed on electron-irradiated Li2O crystals has demonstrated the simultaneous formation of two populations of colloids of metallic lithium, one is associated with oxygen bubbles and a typical size of >10 microm, while the other one consists of nanoclusters in the range of <10 nm. Lithium 148-155 ATP binding cassette subfamily A member 12 Homo sapiens 47-50 12236748-8 2002 Reaction of Li2 with carboxylic acids in DMSO results in acid-dependent decarboxylation of 2(-) with a rate that is dependent on the concentration of the acid and its pK(a). Carboxylic Acids 21-37 ATP binding cassette subfamily A member 12 Homo sapiens 12-15 12236748-8 2002 Reaction of Li2 with carboxylic acids in DMSO results in acid-dependent decarboxylation of 2(-) with a rate that is dependent on the concentration of the acid and its pK(a). Dimethyl Sulfoxide 41-45 ATP binding cassette subfamily A member 12 Homo sapiens 12-15 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. h2 cs 137-142 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. Oxygen 41-47 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. ntbu 143-147 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. Sulfur 216-222 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. Sulfur 57-58 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-1 2001 Through isoelectronic replacement of the oxygen atoms in SO42- ions by one CH2 and three NtBu groups one arrives formally at the dianion H2 CS(NtBu)32- , which has been isolated for the first time in the form of the sulfur(VI) ylide complex [(tmeda)2 Li2 {CH2 S(NtBu)3 }]. ntbu 143-147 ATP binding cassette subfamily A member 12 Homo sapiens 251-254 29712147-3 2001 Hydrolysis favors the formation of the triimidosulfate [{(tmeda)Li2 [OS(NtBu)3 ]}3 ] and methane, and not, as one might expect, diimidomethylenesulfate and the amine. triimidosulfate 39-54 ATP binding cassette subfamily A member 12 Homo sapiens 64-67 11197002-1 2000 The treatment of SiCl4 with 4 equiv of Li2(Nnaph) (naph = 1-naphthyl) in diethyl ether gives (Et2O.Li)4[Si(Nnaph)4] (4), which, upon reaction with excess tBuNH3Cl or MeO3SCF3, generates Si[N(H)naph]4 (5) or Si[N(Me)naph]4 (6), respectively. silicon tetrachloride 17-22 ATP binding cassette subfamily A member 12 Homo sapiens 39-42 10991541-0 2000 Li2VO(Si,Ge)O4, a prototype of a two-dimensional frustrated quantum heisenberg antiferromagnet NMR and magnetization measurements in Li2VOSiO4 and Li2VOGeO4 are reported. li2vosio4 133-142 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 11197002-1 2000 The treatment of SiCl4 with 4 equiv of Li2(Nnaph) (naph = 1-naphthyl) in diethyl ether gives (Et2O.Li)4[Si(Nnaph)4] (4), which, upon reaction with excess tBuNH3Cl or MeO3SCF3, generates Si[N(H)naph]4 (5) or Si[N(Me)naph]4 (6), respectively. naph 44-48 ATP binding cassette subfamily A member 12 Homo sapiens 39-42 11197002-1 2000 The treatment of SiCl4 with 4 equiv of Li2(Nnaph) (naph = 1-naphthyl) in diethyl ether gives (Et2O.Li)4[Si(Nnaph)4] (4), which, upon reaction with excess tBuNH3Cl or MeO3SCF3, generates Si[N(H)naph]4 (5) or Si[N(Me)naph]4 (6), respectively. Ether 73-86 ATP binding cassette subfamily A member 12 Homo sapiens 39-42 11197002-1 2000 The treatment of SiCl4 with 4 equiv of Li2(Nnaph) (naph = 1-naphthyl) in diethyl ether gives (Et2O.Li)4[Si(Nnaph)4] (4), which, upon reaction with excess tBuNH3Cl or MeO3SCF3, generates Si[N(H)naph]4 (5) or Si[N(Me)naph]4 (6), respectively. Ether 94-98 ATP binding cassette subfamily A member 12 Homo sapiens 39-42 29711435-0 1998 The pi-Pyrrole Complexation of Alkali Metal Ions by Zirconium meso-Octaalkylporphyrinogens: Encapsulation of Li4 H4 and Li2 O in Sandwich Structures. pi-pyrrole 4-14 ATP binding cassette subfamily A member 12 Homo sapiens 120-123 29711435-0 1998 The pi-Pyrrole Complexation of Alkali Metal Ions by Zirconium meso-Octaalkylporphyrinogens: Encapsulation of Li4 H4 and Li2 O in Sandwich Structures. Metals 38-43 ATP binding cassette subfamily A member 12 Homo sapiens 120-123 29711435-0 1998 The pi-Pyrrole Complexation of Alkali Metal Ions by Zirconium meso-Octaalkylporphyrinogens: Encapsulation of Li4 H4 and Li2 O in Sandwich Structures. zirconium meso-octaalkylporphyrinogens 52-90 ATP binding cassette subfamily A member 12 Homo sapiens 120-123 34780587-2 2021 In this study, a carborane-fused four-membered boracycle bearing an electron precise B-B bond, 1,2-(BBrSMe2)2-o-C2B10H10, was synthesized via the reaction of 1,2-Li2-o-carborane with B2Br4(SMe2)2. carborane 17-26 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34708583-1 2022 Sluggish sulfur reduction and lithium sulfide (Li2 S) oxidation prevent the widespread use of lithium-sulfur (Li-S) batteries, which are attractive alternatives to Li-ion batteries. lithium sulfide 30-45 ATP binding cassette subfamily A member 12 Homo sapiens 47-50 34708583-3 2022 A combination of synchrotron X-ray absorption spectroscopy and density functional theory calculations show that a highly active heterointerface with charge redistribution and structure distortion effectively immobilizes sulfur species, facilitates Li ion diffusion, and decreases the sulfur reduction and Li2 S oxidation energy barriers. Sulfur 220-226 ATP binding cassette subfamily A member 12 Homo sapiens 305-308 34881754-2 2021 We have now tackled both subjects simultaneously by forming aryl-B bonds via SNAr-type reactions on fluorobenzenes under mild conditions using Na2(FluB BFlu), Li2(HBFlu), and Li2(Me2DBA) (BFlu = 9-borafluorenyl, Me2DBA = 9,10-dimethyl-9,10-dihydro-9,10-diboraanthracene). me2dba 179-185 ATP binding cassette subfamily A member 12 Homo sapiens 175-178 34898005-2 2022 Herein, a lithium vacancy-tuned Li2 CuO2 with square-planar (CuO4 ) layers is developed via an electrochemical delithiation strategy. Lithium 10-17 ATP binding cassette subfamily A member 12 Homo sapiens 32-35 34898005-2 2022 Herein, a lithium vacancy-tuned Li2 CuO2 with square-planar (CuO4 ) layers is developed via an electrochemical delithiation strategy. cuo4 61-65 ATP binding cassette subfamily A member 12 Homo sapiens 32-35 34898005-3 2022 Density functional theory calculations reveal that the lithium vacancies (VLi ) lead to a shorter distance between adjacent (CuO4 ) layers and reduce the coordination number of Li+ around each Cu, featuring with a lower energy barrier for CO CO coupling than pristine Li2 CuO2 without VLi . Lithium 55-62 ATP binding cassette subfamily A member 12 Homo sapiens 268-271 34898005-3 2022 Density functional theory calculations reveal that the lithium vacancies (VLi ) lead to a shorter distance between adjacent (CuO4 ) layers and reduce the coordination number of Li+ around each Cu, featuring with a lower energy barrier for CO CO coupling than pristine Li2 CuO2 without VLi . cuo4 125-129 ATP binding cassette subfamily A member 12 Homo sapiens 268-271 34898005-3 2022 Density functional theory calculations reveal that the lithium vacancies (VLi ) lead to a shorter distance between adjacent (CuO4 ) layers and reduce the coordination number of Li+ around each Cu, featuring with a lower energy barrier for CO CO coupling than pristine Li2 CuO2 without VLi . copper hydroxide 272-276 ATP binding cassette subfamily A member 12 Homo sapiens 268-271 34898005-4 2022 With the VLi percentage of 1.6%, the Li2- x CuO2 catalyst exhibits a high Faradaic efficiency of 90.6 +- 7.6% for C2+ at -0.85 V versus reversible hydrogen electrode without iR correction, and an outstanding partial current density of -706 +- 32 mA cm-2 . copper hydroxide 45-49 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 34898005-4 2022 With the VLi percentage of 1.6%, the Li2- x CuO2 catalyst exhibits a high Faradaic efficiency of 90.6 +- 7.6% for C2+ at -0.85 V versus reversible hydrogen electrode without iR correction, and an outstanding partial current density of -706 +- 32 mA cm-2 . A(2)C 115-117 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 34898005-4 2022 With the VLi percentage of 1.6%, the Li2- x CuO2 catalyst exhibits a high Faradaic efficiency of 90.6 +- 7.6% for C2+ at -0.85 V versus reversible hydrogen electrode without iR correction, and an outstanding partial current density of -706 +- 32 mA cm-2 . Hydrogen 148-156 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. lithium polysulfide 76-95 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. lithium sulfur 136-150 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. li-s 152-156 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. lithium polysulfides 212-232 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. lipss 234-239 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-0 2021 Electron and Ion Co-Conductive Catalyst Achieving Instant Transformation of Lithium Polysulfide towards Li2 S. Most of the catalysts in lithium sulfur (Li-S) batteries present low electronic conductivity and the lithium polysulfides (LiPSs) must diffuse onto the surface of the carbon materials to achieve their conversion reaction. Carbon 278-284 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34658075-1 2021 It is a significant challenge to achieve the instantaneous transformation of LiPSs to Li2 S in Li-S batteries to suppress the shuttle effect of LiPSs. lipss 77-82 ATP binding cassette subfamily A member 12 Homo sapiens 86-89 34658075-1 2021 It is a significant challenge to achieve the instantaneous transformation of LiPSs to Li2 S in Li-S batteries to suppress the shuttle effect of LiPSs. li-s 95-99 ATP binding cassette subfamily A member 12 Homo sapiens 86-89 34658075-2 2021 Herein, a unique electron and ion co-conductive catalyst of carbon-coated Li1.4 Al0.4 Ti1.6 (PO4 )3 (C@LATP) is developed, which not only possesses strong adsorption to LiPSs, but, more importantly, also promotes the instantaneous conversion reaction of LiPSs to Li2 S. The C@LATP nanoparticles as catalytic active sites can synchronously and efficiently provide both Li ions and electrons to facilitate the conversion reaction of LiPSs. Carbon 60-66 ATP binding cassette subfamily A member 12 Homo sapiens 263-266 34658075-2 2021 Herein, a unique electron and ion co-conductive catalyst of carbon-coated Li1.4 Al0.4 Ti1.6 (PO4 )3 (C@LATP) is developed, which not only possesses strong adsorption to LiPSs, but, more importantly, also promotes the instantaneous conversion reaction of LiPSs to Li2 S. The C@LATP nanoparticles as catalytic active sites can synchronously and efficiently provide both Li ions and electrons to facilitate the conversion reaction of LiPSs. po4 ) 93-98 ATP binding cassette subfamily A member 12 Homo sapiens 263-266 34672422-0 2021 Universal-Descriptors-Guided Design of Single Atom Catalysts toward Oxidation of Li2 S in Lithium-Sulfur Batteries. Lithium 90-97 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34672422-0 2021 Universal-Descriptors-Guided Design of Single Atom Catalysts toward Oxidation of Li2 S in Lithium-Sulfur Batteries. Sulfur 98-104 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34672422-1 2021 The sulfur redox kinetics critically matters to superior lithium-sulfur (Li-S) batteries, for which single atom catalysts (SACs) take effect on promoting Li2 S redox process and mitigating the shuttle behavior of lithium polysulfide (LiPs). Sulfur 4-10 ATP binding cassette subfamily A member 12 Homo sapiens 154-157 34672422-1 2021 The sulfur redox kinetics critically matters to superior lithium-sulfur (Li-S) batteries, for which single atom catalysts (SACs) take effect on promoting Li2 S redox process and mitigating the shuttle behavior of lithium polysulfide (LiPs). Lithium 57-64 ATP binding cassette subfamily A member 12 Homo sapiens 154-157 34672422-1 2021 The sulfur redox kinetics critically matters to superior lithium-sulfur (Li-S) batteries, for which single atom catalysts (SACs) take effect on promoting Li2 S redox process and mitigating the shuttle behavior of lithium polysulfide (LiPs). Sulfur 65-71 ATP binding cassette subfamily A member 12 Homo sapiens 154-157 34672422-1 2021 The sulfur redox kinetics critically matters to superior lithium-sulfur (Li-S) batteries, for which single atom catalysts (SACs) take effect on promoting Li2 S redox process and mitigating the shuttle behavior of lithium polysulfide (LiPs). li-s 73-77 ATP binding cassette subfamily A member 12 Homo sapiens 154-157 34773370-4 2021 MoO3 with a reversible lithiation/delithiation behavior between Li0.042 MoO3 and Li2 MoO4 within 1.7-2.8 V versus Li/Li+ combines the Li+ insertion and LiPSs immobilization and efficiently improve the LSBs redox kinetics. molybdenum trioxide 0-4 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34773370-4 2021 MoO3 with a reversible lithiation/delithiation behavior between Li0.042 MoO3 and Li2 MoO4 within 1.7-2.8 V versus Li/Li+ combines the Li+ insertion and LiPSs immobilization and efficiently improve the LSBs redox kinetics. 4-(4-Benzyl-4-Methoxypiperidin-1-Yl)-N-[(4-{[1,1-Dimethyl-2-(Phenylthio)ethyl]amino}-3-Nitrophenyl)sulfonyl]benzamide 64-67 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 9398541-0 1997 Dipole Polarizabilities of Li, C, and O and Long-Range Coefficients for Various Molecular States of Li2, CO, and O2 Dynamic polarizabilities with imaginary frequencies are calculated for Li(2s 2S), Li(3s 2S), Li(2p 2P), C(2p2 3P), and O(2p4 3P) atoms with a time-dependent gauge-invariant method. dipole 0-6 ATP binding cassette subfamily A member 12 Homo sapiens 100-103 9398541-0 1997 Dipole Polarizabilities of Li, C, and O and Long-Range Coefficients for Various Molecular States of Li2, CO, and O2 Dynamic polarizabilities with imaginary frequencies are calculated for Li(2s 2S), Li(3s 2S), Li(2p 2P), C(2p2 3P), and O(2p4 3P) atoms with a time-dependent gauge-invariant method. li(2s 2s) 187-196 ATP binding cassette subfamily A member 12 Homo sapiens 100-103 9398541-0 1997 Dipole Polarizabilities of Li, C, and O and Long-Range Coefficients for Various Molecular States of Li2, CO, and O2 Dynamic polarizabilities with imaginary frequencies are calculated for Li(2s 2S), Li(3s 2S), Li(2p 2P), C(2p2 3P), and O(2p4 3P) atoms with a time-dependent gauge-invariant method. li(3s 2s 198-206 ATP binding cassette subfamily A member 12 Homo sapiens 100-103 10061318-0 1996 Spectroscopic evidence for large ( >> 1 microm) lithium-colloid creation in electron-irradiated Li2O single crystals. Lithium 54-61 ATP binding cassette subfamily A member 12 Homo sapiens 102-105 34677911-1 2021 Engineering oxygen vacancy and boosting Li2 O reversibility on oxides-based electrode are of significance but remains a challenge in high-power lithium-ion batteries. Oxides 63-69 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34677911-1 2021 Engineering oxygen vacancy and boosting Li2 O reversibility on oxides-based electrode are of significance but remains a challenge in high-power lithium-ion batteries. Lithium 144-151 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34677911-3 2021 Density functional theory calculations unveil the SnO2- x /Fe2 O3 with a maximum x value has the optimal electronic structure, the metallic Fe generated from Fe2 O3 can markedly reduce the free energy to break Li-O bonds for accelerating subsequent delithiation process of Li2 O. Consequently, the optimized SnO2- x /Fe2 O3 exhibits a remarkably enhanced electrochemical reversibility and reaction kinetics. Iron 140-142 ATP binding cassette subfamily A member 12 Homo sapiens 273-276 34677911-3 2021 Density functional theory calculations unveil the SnO2- x /Fe2 O3 with a maximum x value has the optimal electronic structure, the metallic Fe generated from Fe2 O3 can markedly reduce the free energy to break Li-O bonds for accelerating subsequent delithiation process of Li2 O. Consequently, the optimized SnO2- x /Fe2 O3 exhibits a remarkably enhanced electrochemical reversibility and reaction kinetics. fe2 o3 158-164 ATP binding cassette subfamily A member 12 Homo sapiens 273-276 34677911-5 2021 This work provides the possibilities for skillfully regulating oxygen vacancy and meantime enhancing Li2 O reversibility. Oxygen 63-69 ATP binding cassette subfamily A member 12 Homo sapiens 101-104 34780587-2 2021 In this study, a carborane-fused four-membered boracycle bearing an electron precise B-B bond, 1,2-(BBrSMe2)2-o-C2B10H10, was synthesized via the reaction of 1,2-Li2-o-carborane with B2Br4(SMe2)2. boracycle 47-56 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34773370-4 2021 MoO3 with a reversible lithiation/delithiation behavior between Li0.042 MoO3 and Li2 MoO4 within 1.7-2.8 V versus Li/Li+ combines the Li+ insertion and LiPSs immobilization and efficiently improve the LSBs redox kinetics. molybdenum trioxide 72-76 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34780587-2 2021 In this study, a carborane-fused four-membered boracycle bearing an electron precise B-B bond, 1,2-(BBrSMe2)2-o-C2B10H10, was synthesized via the reaction of 1,2-Li2-o-carborane with B2Br4(SMe2)2. 1,2-(bbrsme2)2-o-c2b10h10 95-120 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34773370-4 2021 MoO3 with a reversible lithiation/delithiation behavior between Li0.042 MoO3 and Li2 MoO4 within 1.7-2.8 V versus Li/Li+ combines the Li+ insertion and LiPSs immobilization and efficiently improve the LSBs redox kinetics. moo4 85-89 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34787135-0 2021 Enhanced electrochemical performance of Li2.72Na0.31MnPO4CO3 as a cathode material in "water-in-salt" electrolytes. .31mnpo4co3 49-60 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34787135-0 2021 Enhanced electrochemical performance of Li2.72Na0.31MnPO4CO3 as a cathode material in "water-in-salt" electrolytes. Water 87-92 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34780587-2 2021 In this study, a carborane-fused four-membered boracycle bearing an electron precise B-B bond, 1,2-(BBrSMe2)2-o-C2B10H10, was synthesized via the reaction of 1,2-Li2-o-carborane with B2Br4(SMe2)2. b2br4(sme2) 183-194 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34787135-0 2021 Enhanced electrochemical performance of Li2.72Na0.31MnPO4CO3 as a cathode material in "water-in-salt" electrolytes. Salts 96-100 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34751686-2 2021 Instead of employing complicated treatment with high alkali concentration, the self-organization reaction between lithium and titanium ions in the prepared ion precursor can enable the formation of layered lithium titanate crystals (Li2-xHxTi2O5, where x = 0.1 and 1.52 for as-synthesise and acid-treated samples, respectively) under low alkaline conditions. Lithium 114-121 ATP binding cassette subfamily A member 12 Homo sapiens 233-236 34787135-1 2021 A carbonophosphate compound of Li2.72Na0.31MnPO4CO3 was synthesized via ion exchange. carbonophosphate 2-18 ATP binding cassette subfamily A member 12 Homo sapiens 31-34 34773370-4 2021 MoO3 with a reversible lithiation/delithiation behavior between Li0.042 MoO3 and Li2 MoO4 within 1.7-2.8 V versus Li/Li+ combines the Li+ insertion and LiPSs immobilization and efficiently improve the LSBs redox kinetics. lipss 152-157 ATP binding cassette subfamily A member 12 Homo sapiens 81-84 34751686-2 2021 Instead of employing complicated treatment with high alkali concentration, the self-organization reaction between lithium and titanium ions in the prepared ion precursor can enable the formation of layered lithium titanate crystals (Li2-xHxTi2O5, where x = 0.1 and 1.52 for as-synthesise and acid-treated samples, respectively) under low alkaline conditions. Titanium 126-134 ATP binding cassette subfamily A member 12 Homo sapiens 233-236 34751686-2 2021 Instead of employing complicated treatment with high alkali concentration, the self-organization reaction between lithium and titanium ions in the prepared ion precursor can enable the formation of layered lithium titanate crystals (Li2-xHxTi2O5, where x = 0.1 and 1.52 for as-synthesise and acid-treated samples, respectively) under low alkaline conditions. Lithiumtitanate 206-222 ATP binding cassette subfamily A member 12 Homo sapiens 233-236 34425027-7 2021 As a representative example, Li2 S is in situ implanted into a hierarchical porous cross-linked puffed carbon (CPC) matrix to verify its application in lithium-sulfur batteries. Carbon 103-109 ATP binding cassette subfamily A member 12 Homo sapiens 29-32 34425027-7 2021 As a representative example, Li2 S is in situ implanted into a hierarchical porous cross-linked puffed carbon (CPC) matrix to verify its application in lithium-sulfur batteries. cpc 111-114 ATP binding cassette subfamily A member 12 Homo sapiens 29-32 34425027-7 2021 As a representative example, Li2 S is in situ implanted into a hierarchical porous cross-linked puffed carbon (CPC) matrix to verify its application in lithium-sulfur batteries. Sulfur 160-166 ATP binding cassette subfamily A member 12 Homo sapiens 29-32 34425027-8 2021 The designed S-doped CPC/Li2 S cathode shows superior electrochemical performance with higher rate capacity (621 mAh g-1 at 2 C), smaller polarization and enhanced long-term cycles as compared to other counterparts. cpc 21-24 ATP binding cassette subfamily A member 12 Homo sapiens 25-28 34463382-3 2021 Herein, selective dual-defect engineering (i.e., introducing both N-doping and Se-vacancies) of a common MoSe2 electrocatalyst is used to manipulate the bidirectional Li2 S redox. Nitrogen 66-67 ATP binding cassette subfamily A member 12 Homo sapiens 167-170 34927940-5 2021 The single atomic Co shows the best charge transfer/kinetic toward sulfur redox, especially for the rate-determining reaction (Li2 S4 Li2 S) as demonstrated by the significantly lowered energy barrier for Li2 S nucleation/dissolution. Sulfur 67-73 ATP binding cassette subfamily A member 12 Homo sapiens 127-130 34927940-5 2021 The single atomic Co shows the best charge transfer/kinetic toward sulfur redox, especially for the rate-determining reaction (Li2 S4 Li2 S) as demonstrated by the significantly lowered energy barrier for Li2 S nucleation/dissolution. Sulfur 67-73 ATP binding cassette subfamily A member 12 Homo sapiens 137-140 34927940-5 2021 The single atomic Co shows the best charge transfer/kinetic toward sulfur redox, especially for the rate-determining reaction (Li2 S4 Li2 S) as demonstrated by the significantly lowered energy barrier for Li2 S nucleation/dissolution. Sulfur 67-73 ATP binding cassette subfamily A member 12 Homo sapiens 208-211 34338356-3 2021 The proof-of-concept Indium (In)-based catalyst targetedly decelerates the solid-liquid conversion, dissolution of elemental sulfur to polysulfides, while accelerates the liquid-solid conversion, deposition of polysulfides into insoluble Li2 S, which basically reduces accumulation of polysulfides in electrolyte, finally inhibiting the shuttle effect. Indium 21-27 ATP binding cassette subfamily A member 12 Homo sapiens 238-241 34478277-5 2021 In addition, metal ion exchange was fueled enabling off-equilibrium oscillations between rotors (Li2(1))2+ (Ag2(1))2+. Metals 13-18 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34478277-5 2021 In addition, metal ion exchange was fueled enabling off-equilibrium oscillations between rotors (Li2(1))2+ (Ag2(1))2+. ag2(1) 110-116 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34338356-3 2021 The proof-of-concept Indium (In)-based catalyst targetedly decelerates the solid-liquid conversion, dissolution of elemental sulfur to polysulfides, while accelerates the liquid-solid conversion, deposition of polysulfides into insoluble Li2 S, which basically reduces accumulation of polysulfides in electrolyte, finally inhibiting the shuttle effect. polysulfide 210-222 ATP binding cassette subfamily A member 12 Homo sapiens 238-241 34338356-3 2021 The proof-of-concept Indium (In)-based catalyst targetedly decelerates the solid-liquid conversion, dissolution of elemental sulfur to polysulfides, while accelerates the liquid-solid conversion, deposition of polysulfides into insoluble Li2 S, which basically reduces accumulation of polysulfides in electrolyte, finally inhibiting the shuttle effect. polysulfide 285-297 ATP binding cassette subfamily A member 12 Homo sapiens 238-241 34928050-4 2021 The S-doped Co0.85 Se exhibited an outstanding electrocatalytic effect on lithium polysulfides conversion and can induce and regulate uniform growth of insoluble Li2 S on its surface due to the synergistic adsorption by Se and S. As a result, the S/C cathode achieved a high initial capacity of 1340.6 mAh g-1 at 0.5 C and a stable cycling capacity of 666.6 mAh g-1 at 1 C after 500 cycles by 5 wt% Co0.85 SeS additions. CO0 12-15 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34928050-4 2021 The S-doped Co0.85 Se exhibited an outstanding electrocatalytic effect on lithium polysulfides conversion and can induce and regulate uniform growth of insoluble Li2 S on its surface due to the synergistic adsorption by Se and S. As a result, the S/C cathode achieved a high initial capacity of 1340.6 mAh g-1 at 0.5 C and a stable cycling capacity of 666.6 mAh g-1 at 1 C after 500 cycles by 5 wt% Co0.85 SeS additions. Selenium 220-222 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34928050-4 2021 The S-doped Co0.85 Se exhibited an outstanding electrocatalytic effect on lithium polysulfides conversion and can induce and regulate uniform growth of insoluble Li2 S on its surface due to the synergistic adsorption by Se and S. As a result, the S/C cathode achieved a high initial capacity of 1340.6 mAh g-1 at 0.5 C and a stable cycling capacity of 666.6 mAh g-1 at 1 C after 500 cycles by 5 wt% Co0.85 SeS additions. CO0 399-402 ATP binding cassette subfamily A member 12 Homo sapiens 162-165 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. magnesium ion 115-119 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34445657-9 2021 We also present the vertical ionization potentials of the Li2 anion at the geometry of the anion ground state. Anions 91-96 ATP binding cassette subfamily A member 12 Homo sapiens 58-61 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. Manganese(2+) 123-127 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. dobdc4 129-135 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. 2,5-dioxido-1,4-benzenedicarboxylate 139-175 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. Metals 226-231 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34309388-4 2021 Herein, we report on electrically conducting Li-ion MOF cathodes with the generic formula Li2-M-DOBDC (wherein M = Mg2+ or Mn2+; DOBDC4- = 2,5-dioxido-1,4-benzenedicarboxylate), by rational control of the ligand to transition metal stoichiometry and secondary building unit (SBU) topology in the archetypal CPO-27. cpo 307-310 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 34309388-5 2021 The accurate chemical and structural changes not only enable reversible redox but also induce a million-fold electrical conductivity increase by virtue of efficient electronic self-exchange facilitated by mix-in redox: 10-7 S/cm for Li2-Mn-DOBDC vs 10-13 S/cm for the isoreticular H2-Mn-DOBDC and Li2-Mg-DOBDC, or the Mn-CPO-27 compositional analogues. dobdc 240-245 ATP binding cassette subfamily A member 12 Homo sapiens 233-236 34309388-7 2021 As a particular cathode material, Li2-Mn-DOBDC displays an average discharge potential of 3.2 V vs Li+/Li0, demonstrates excellent capacity retention over 100 cycles, while also handling fast cycling rates, inherent to the intrinsic electronic conductivity. 4-(4-Benzyl-4-Methoxypiperidin-1-Yl)-N-[(4-{[1,1-Dimethyl-2-(Phenylthio)ethyl]amino}-3-Nitrophenyl)sulfonyl]benzamide 103-106 ATP binding cassette subfamily A member 12 Homo sapiens 34-37 34095936-2 2021 Here, a series of novel mechanoluminescent phosphors Li2-xMgGeO4:xMn2+ (0 <= x <= 0.025) were synthesized via a high-temperature solid-state reaction method in an ambient atmosphere. phosphors 43-52 ATP binding cassette subfamily A member 12 Homo sapiens 53-56 34197017-3 2021 In view of these factors, Ti4+ -substituted Li2 IrO3 (Li2 Ir0.75 Ti0.25 O3 ) is synthesized, which undergoes an oxygen redox reaction with suppressed voltage decay, yielding improved electrochemical performance and good capacity retention. Oxygen 112-118 ATP binding cassette subfamily A member 12 Homo sapiens 44-47 34197017-3 2021 In view of these factors, Ti4+ -substituted Li2 IrO3 (Li2 Ir0.75 Ti0.25 O3 ) is synthesized, which undergoes an oxygen redox reaction with suppressed voltage decay, yielding improved electrochemical performance and good capacity retention. Oxygen 112-118 ATP binding cassette subfamily A member 12 Homo sapiens 54-57 34197017-4 2021 It is shown that the increased bond covalency upon Ti4+ substitution results in structural stability, tuning the phase stability from O3 to O1" upon de-lithiation during charging compared with O3 to T3 and O1 for pristine Li2 IrO3 , thereby facilitating the oxidation of oxygen. ti4+ 51-55 ATP binding cassette subfamily A member 12 Homo sapiens 222-225 34197017-4 2021 It is shown that the increased bond covalency upon Ti4+ substitution results in structural stability, tuning the phase stability from O3 to O1" upon de-lithiation during charging compared with O3 to T3 and O1 for pristine Li2 IrO3 , thereby facilitating the oxidation of oxygen. Oxygen 271-277 ATP binding cassette subfamily A member 12 Homo sapiens 222-225 34145629-1 2021 Critical drawbacks, including sluggish redox kinetics and undesirable shuttling of polysulfides (Li2 Sn , n = 4-8), seriously deteriorate the electrochemical performance of high-energy-density lithium-sulfur (Li-S) batteries. polysulfide 83-95 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34145629-1 2021 Critical drawbacks, including sluggish redox kinetics and undesirable shuttling of polysulfides (Li2 Sn , n = 4-8), seriously deteriorate the electrochemical performance of high-energy-density lithium-sulfur (Li-S) batteries. Lithium 193-200 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34145629-1 2021 Critical drawbacks, including sluggish redox kinetics and undesirable shuttling of polysulfides (Li2 Sn , n = 4-8), seriously deteriorate the electrochemical performance of high-energy-density lithium-sulfur (Li-S) batteries. Sulfur 201-207 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34145629-1 2021 Critical drawbacks, including sluggish redox kinetics and undesirable shuttling of polysulfides (Li2 Sn , n = 4-8), seriously deteriorate the electrochemical performance of high-energy-density lithium-sulfur (Li-S) batteries. li-s 209-213 ATP binding cassette subfamily A member 12 Homo sapiens 97-100 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. sa 4-6 ATP binding cassette subfamily A member 12 Homo sapiens 222-225 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. sa 4-6 ATP binding cassette subfamily A member 12 Homo sapiens 244-247 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. Iron 7-9 ATP binding cassette subfamily A member 12 Homo sapiens 222-225 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. Iron 7-9 ATP binding cassette subfamily A member 12 Homo sapiens 244-247 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. fe2 n 56-61 ATP binding cassette subfamily A member 12 Homo sapiens 222-225 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. fe2 n 56-61 ATP binding cassette subfamily A member 12 Homo sapiens 244-247 34145629-3 2021 The SA-Fe, with plane-symmetric Fe-4N coordination, and Fe2 N, with triangular pyramidal Fe-3N coordination, in this well-designed configuration exhibit synergistic adsorption of polysulfides and catalytic selectivity for Li2 Sn lithiation and Li2 S delithiation, respectively. polysulfide 179-191 ATP binding cassette subfamily A member 12 Homo sapiens 244-247 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. sa-fe 32-37 ATP binding cassette subfamily A member 12 Homo sapiens 187-190 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. sa-fe 32-37 ATP binding cassette subfamily A member 12 Homo sapiens 195-198 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. fe2 n 38-43 ATP binding cassette subfamily A member 12 Homo sapiens 187-190 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. fe2 n 38-43 ATP binding cassette subfamily A member 12 Homo sapiens 195-198 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. polysulfide 82-94 ATP binding cassette subfamily A member 12 Homo sapiens 187-190 34145629-4 2021 These characteristics endow the SA-Fe/Fe2 N@NG-modified separator with an optimal polysulfides confinement-catalysis ability, thus accelerating the bidirectional liquid-solid conversion (Li2 Sn Li2 S) and suppressing the shuttle effect. polysulfide 82-94 ATP binding cassette subfamily A member 12 Homo sapiens 195-198 34095936-2 2021 Here, a series of novel mechanoluminescent phosphors Li2-xMgGeO4:xMn2+ (0 <= x <= 0.025) were synthesized via a high-temperature solid-state reaction method in an ambient atmosphere. xmn2+ 65-70 ATP binding cassette subfamily A member 12 Homo sapiens 53-56 34597626-8 2021 Depletion of ABCA12, implicated in GlcCer transport, preferentially decreased neutral GSL levels, while ABCB1 KD preferentially reduced gangliosides, but increased neutral GSL Gb3. Glucosylceramides 35-41 ATP binding cassette subfamily A member 12 Homo sapiens 13-19 34349910-2 2021 We considered two HeLi2 clusters - with Li2 being either in the singlet electronic ground state or in the triplet first excited state - in which ETMD takes place after ionization of He. Helium 182-184 ATP binding cassette subfamily A member 12 Homo sapiens 40-43 34349910-3 2021 The electron transfer from Li2 to He+ leads to the emission of another electron from Li2 into the continuum. Helium 34-36 ATP binding cassette subfamily A member 12 Homo sapiens 27-30 34349910-3 2021 The electron transfer from Li2 to He+ leads to the emission of another electron from Li2 into the continuum. Helium 34-36 ATP binding cassette subfamily A member 12 Homo sapiens 85-88 34349910-4 2021 Due to the weak binding of He to Li2 in the initial states of both clusters, the involved nuclear wavepackets are very extended. Helium 27-29 ATP binding cassette subfamily A member 12 Homo sapiens 33-36 34105278-0 2021 Epitaxial Growth of Nanostructured Li2 Se on Lithium Metal for All Solid-State Batteries. lithium metal 45-58 ATP binding cassette subfamily A member 12 Homo sapiens 35-38 34105278-4 2021 In this work, nanostructured Li2 Se epitaxially grown on Li metal by chemical vapor deposition are investigated as a protective layer. li metal 57-65 ATP binding cassette subfamily A member 12 Homo sapiens 29-32 34105278-5 2021 By adjusting reaction time and cooling rate, a morphology of as-prepared Li2 Se is controlled, resulting in nanoparticles, nanorods, or nanowalls with a dominant (220) plane parallel to the (110) plane of the Li metal substrate. li metal 209-217 ATP binding cassette subfamily A member 12 Homo sapiens 73-76 34105278-7 2021 Dual compatibility of the Li2 Se layers with strong chemical bonds to Li metal and uniform physical contact to a Li6 PS5 Csulfide electrolyte prevents undesirable side reactions and enables a homogeneous charge transfer at the interface upon cycling. li metal 70-78 ATP binding cassette subfamily A member 12 Homo sapiens 26-29 34105278-7 2021 Dual compatibility of the Li2 Se layers with strong chemical bonds to Li metal and uniform physical contact to a Li6 PS5 Csulfide electrolyte prevents undesirable side reactions and enables a homogeneous charge transfer at the interface upon cycling. csulfide 121-129 ATP binding cassette subfamily A member 12 Homo sapiens 26-29 34105278-8 2021 As a result, a full cell coupled with a LiCoO2 -based cathode shows significantly enhanced electrochemical performance and demonstrates the practical use of Li anodes with Li2 Se layers for all solid-state battery applications. licoo2 40-46 ATP binding cassette subfamily A member 12 Homo sapiens 172-175 34597626-8 2021 Depletion of ABCA12, implicated in GlcCer transport, preferentially decreased neutral GSL levels, while ABCB1 KD preferentially reduced gangliosides, but increased neutral GSL Gb3. Glycosphingolipids 86-89 ATP binding cassette subfamily A member 12 Homo sapiens 13-19 34597626-8 2021 Depletion of ABCA12, implicated in GlcCer transport, preferentially decreased neutral GSL levels, while ABCB1 KD preferentially reduced gangliosides, but increased neutral GSL Gb3. Glycosphingolipids 172-175 ATP binding cassette subfamily A member 12 Homo sapiens 13-19 35524983-2 2022 Herein, we propose a high-energy and safe quasi-solid-state lithium battery by solid-state redox chemistry of polymer-based molecular Li2 S cathode in fireproof gel electrolyte. Lithium 60-67 ATP binding cassette subfamily A member 12 Homo sapiens 134-137 35411708-0 2022 High-Density Oxygen Doping of Conductive Metal Sulfides for Better Polysulfide Trapping and Li2 S-S8 Redox Kinetics in High Areal Capacity Lithium-Sulfur Batteries. metal sulfides 41-55 ATP binding cassette subfamily A member 12 Homo sapiens 92-95 35411708-4 2022 Taking the advantages of high conductivity, chemical stability, the introduced large Li-O interactions, and activated Co (Ni) facets for catalyzing Sn 2- , the NiCo2 (O-S)4 is able to accelerate the Li2 S-S8 redox kinetics. Tin 148-150 ATP binding cassette subfamily A member 12 Homo sapiens 199-202 35411708-4 2022 Taking the advantages of high conductivity, chemical stability, the introduced large Li-O interactions, and activated Co (Ni) facets for catalyzing Sn 2- , the NiCo2 (O-S)4 is able to accelerate the Li2 S-S8 redox kinetics. nico2 (o-s)4 160-172 ATP binding cassette subfamily A member 12 Homo sapiens 199-202 35524983-2 2022 Herein, we propose a high-energy and safe quasi-solid-state lithium battery by solid-state redox chemistry of polymer-based molecular Li2 S cathode in fireproof gel electrolyte. Polymers 110-117 ATP binding cassette subfamily A member 12 Homo sapiens 134-137 35524983-4 2022 The molecular Li2 S cathode exhibits an exceptional lifetime of 2000 cycles, 100% Coulombic efficiency, high capacity of 830 mAh g-1 with ultralow capacity loss of 0.005 - 0.01% per cycle and superior rate capability up to 10 C. Meanwhile, it shows high stability in the carbonate-involved electrolyte for maximizing the compatibility with carbonate-efficient Si anode. Carbonates 271-280 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35524983-4 2022 The molecular Li2 S cathode exhibits an exceptional lifetime of 2000 cycles, 100% Coulombic efficiency, high capacity of 830 mAh g-1 with ultralow capacity loss of 0.005 - 0.01% per cycle and superior rate capability up to 10 C. Meanwhile, it shows high stability in the carbonate-involved electrolyte for maximizing the compatibility with carbonate-efficient Si anode. Carbonates 340-349 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35524983-4 2022 The molecular Li2 S cathode exhibits an exceptional lifetime of 2000 cycles, 100% Coulombic efficiency, high capacity of 830 mAh g-1 with ultralow capacity loss of 0.005 - 0.01% per cycle and superior rate capability up to 10 C. Meanwhile, it shows high stability in the carbonate-involved electrolyte for maximizing the compatibility with carbonate-efficient Si anode. Silicon 360-362 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35524983-6 2022 A fire-retardant composite gel electrolyte is developed to further strengthen the intrinsic safe redox between Li2 S cathode and Si anode, which secures remarkable safety against extreme abuse of overheating, short circuits and mechanical damage in the air/water or even on fire. Silicon 129-131 ATP binding cassette subfamily A member 12 Homo sapiens 111-114 35524983-6 2022 A fire-retardant composite gel electrolyte is developed to further strengthen the intrinsic safe redox between Li2 S cathode and Si anode, which secures remarkable safety against extreme abuse of overheating, short circuits and mechanical damage in the air/water or even on fire. Water 257-262 ATP binding cassette subfamily A member 12 Homo sapiens 111-114 35085402-6 2022 Density functional theory studies confirm that the build-in interfacial field and sulfur vacancy can promote the thermodynamic formation and decomposition of Li2 S, thus improve their intrinsic activity. Sulfur 82-88 ATP binding cassette subfamily A member 12 Homo sapiens 158-161 35466540-3 2022 beta-Li3 PS4 (beta-LPS) is the most studied member of the Li2 S-P2 S5 family, offering promising properties for implementation in electric vehicles. beta-li3 0-8 ATP binding cassette subfamily A member 12 Homo sapiens 58-61 35466540-3 2022 beta-Li3 PS4 (beta-LPS) is the most studied member of the Li2 S-P2 S5 family, offering promising properties for implementation in electric vehicles. beta-lps 14-22 ATP binding cassette subfamily A member 12 Homo sapiens 58-61 34994990-0 2022 Air-Stable High-Nickel Cathode with Reinforced Electrochemical Performance Enabled by Convertible Amorphous Li2 CO3 Modification. Nickel 16-22 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 34994990-3 2022 Herein, a stable high-nickel cathode was rationally designed via in-situ induction of a dense amorphous Li2 CO3 on the particle surface by a preemptive atmosphere control. Nickel 22-28 ATP binding cassette subfamily A member 12 Homo sapiens 104-107 34994990-4 2022 Among the residual lithium compounds, Li2 CO3 is the most thermodynamically stable one so that the dense Li2 CO3 coating layer can serve as a physical protection layer to isolate the cathodes from contact with moist air. Lithium 19-26 ATP binding cassette subfamily A member 12 Homo sapiens 38-41 34994990-4 2022 Among the residual lithium compounds, Li2 CO3 is the most thermodynamically stable one so that the dense Li2 CO3 coating layer can serve as a physical protection layer to isolate the cathodes from contact with moist air. Lithium 19-26 ATP binding cassette subfamily A member 12 Homo sapiens 105-108 34994990-8 2022 This work opens a valuable perspective on the evolution of amorphous Li2 CO3 in LIBs and provides guidance on protecting unstable high-capacity cathodes for energy storage devices. libs 80-84 ATP binding cassette subfamily A member 12 Homo sapiens 69-72 35174998-2 2022 However, the poor conductivity of sulfur and Li2 S, as well as the shuttling effect of lithium polysulfides, seriously limits their commercialization. lithium polysulfides 87-107 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 35113524-6 2022 The optimized Li2.6Er0.6Zr0.4Cl6 electrolyte exhibits both a high ionic conductivity of 1.13 mS cm-1 and a high oxidation voltage of 4.21 V. Furthermore, carbon additives are demonstrated to be beneficial for achieving high discharge capacity and better cycling stability and rate performance for halide-based ASSLIBs, which are completely different from the case of sulfide electrolytes. Carbon 154-160 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35113524-6 2022 The optimized Li2.6Er0.6Zr0.4Cl6 electrolyte exhibits both a high ionic conductivity of 1.13 mS cm-1 and a high oxidation voltage of 4.21 V. Furthermore, carbon additives are demonstrated to be beneficial for achieving high discharge capacity and better cycling stability and rate performance for halide-based ASSLIBs, which are completely different from the case of sulfide electrolytes. halide 297-303 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35113524-6 2022 The optimized Li2.6Er0.6Zr0.4Cl6 electrolyte exhibits both a high ionic conductivity of 1.13 mS cm-1 and a high oxidation voltage of 4.21 V. Furthermore, carbon additives are demonstrated to be beneficial for achieving high discharge capacity and better cycling stability and rate performance for halide-based ASSLIBs, which are completely different from the case of sulfide electrolytes. Sulfides 367-374 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 35014793-4 2022 Rietveld refinement of ex situ powder X-ray diffraction showed that a Li-deficient phase of Li2O2, Li2-xO2, formed when discharging and was present over the course of charging. Li2O2 92-97 ATP binding cassette subfamily A member 12 Homo sapiens 99-102 33899278-0 2021 Poor Stability of Li2 CO3 in the Solid Electrolyte Interphase of a Lithium-Metal Anode Revealed by Cryo-Electron Microscopy. Lithium 67-74 ATP binding cassette subfamily A member 12 Homo sapiens 18-21 35041287-0 2022 Li2 O2 Formation Electrochemistry and Its Influence on Oxygen Reduction/Evolution Reaction Kinetics in Aprotic Li-O2 Batteries. Oxygen 55-61 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 35041287-0 2022 Li2 O2 Formation Electrochemistry and Its Influence on Oxygen Reduction/Evolution Reaction Kinetics in Aprotic Li-O2 Batteries. li-o2 111-116 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 35041287-2 2022 The key electrochemistry of a nonaqueous Li-O2 battery highly relies on the formation of Li2 O2 during discharge and its reversible decomposition during charge. li-o2 41-46 ATP binding cassette subfamily A member 12 Homo sapiens 89-92 35041287-5 2022 The first part of this review elaborates the Li2 O2 formation mechanism and its relationship with the oxygen reduction reaction/oxygen evolution reaction electrochemistry. Oxygen 102-108 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 35041287-5 2022 The first part of this review elaborates the Li2 O2 formation mechanism and its relationship with the oxygen reduction reaction/oxygen evolution reaction electrochemistry. Oxygen 128-134 ATP binding cassette subfamily A member 12 Homo sapiens 45-48 35041287-9 2022 Further prospects of the ways in making advanced Li-O2 batteries by control of favorable Li2 O2 formation are highlighted, which are valuable for practical construction of aprotic lithium-oxygen batteries. li-o2 49-54 ATP binding cassette subfamily A member 12 Homo sapiens 89-92 35041287-9 2022 Further prospects of the ways in making advanced Li-O2 batteries by control of favorable Li2 O2 formation are highlighted, which are valuable for practical construction of aprotic lithium-oxygen batteries. Lithium 180-187 ATP binding cassette subfamily A member 12 Homo sapiens 89-92 35041287-9 2022 Further prospects of the ways in making advanced Li-O2 batteries by control of favorable Li2 O2 formation are highlighted, which are valuable for practical construction of aprotic lithium-oxygen batteries. Oxygen 188-194 ATP binding cassette subfamily A member 12 Homo sapiens 89-92 6414528-4 1983 Cholesterol-SRA was relatively low in the other groups, but increased progressively, giving a biphasic response: C1-14C derived from from linoleic and arachidonic acids was actively incorporated into cholesterol during the first hours, as compared to C1-14C derived from oleic acid, but stabilized between 6 and 12 h for the LI2 and AR2 group SF incubation. c1-14c 113-119 ATP binding cassette subfamily A member 12 Homo sapiens 325-328 33899278-0 2021 Poor Stability of Li2 CO3 in the Solid Electrolyte Interphase of a Lithium-Metal Anode Revealed by Cryo-Electron Microscopy. Metals 75-80 ATP binding cassette subfamily A member 12 Homo sapiens 18-21 33899278-5 2021 Sulfur-containing additives cause the SEI to preferentially generate Li2 SO4 and overlithiated lithium sulfate and lithium oxide, which encapsulate lithium carbonate in the middle, limiting SEI thickening and enhancing battery life by a factor of ten. Sulfur 0-6 ATP binding cassette subfamily A member 12 Homo sapiens 69-72 33899278-5 2021 Sulfur-containing additives cause the SEI to preferentially generate Li2 SO4 and overlithiated lithium sulfate and lithium oxide, which encapsulate lithium carbonate in the middle, limiting SEI thickening and enhancing battery life by a factor of ten. Lithium Carbonate 148-165 ATP binding cassette subfamily A member 12 Homo sapiens 69-72 32627911-2 2020 A bidirectional catalyst design, oxide-sulfide heterostructure, is proposed to accelerate both reduction of soluble polysulfides and oxidation of insoluble discharge products (e.g., Li2 S), indicating a fundamental way for improving both the cycling stability and sulfur utilization. Oxides 33-38 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 33987896-5 2021 The ultrasmall and highly conductive Mo2 C nanocrystals are confined in the carbon nanosheets and expose more active sites for anchoring and conversion of lithium polysulfides and increase the number of the nuclei for Li2 S2 /Li2 S precipitation. mo2 c 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 218-221 33887114-3 2021 CoNi@MPC exhibits multiple Co-Ni active sites, able to catalyze the reactions of soluble polysulfides, specifically accelerating the generation and decomposition of insoluble Li2 S in lithiation and delithiation process testified by the electrochemical results and density functional theory calculation. polysulfide 89-101 ATP binding cassette subfamily A member 12 Homo sapiens 175-178 33917809-0 2021 Li2(BH4)(NH2) Nanoconfined in SBA-15 as Solid-State Electrolyte for Lithium Batteries. sapropterin 4-7 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 33917809-0 2021 Li2(BH4)(NH2) Nanoconfined in SBA-15 as Solid-State Electrolyte for Lithium Batteries. Amido radical 9-12 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 33917809-0 2021 Li2(BH4)(NH2) Nanoconfined in SBA-15 as Solid-State Electrolyte for Lithium Batteries. SBA-15 30-36 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 33917809-0 2021 Li2(BH4)(NH2) Nanoconfined in SBA-15 as Solid-State Electrolyte for Lithium Batteries. Lithium 68-75 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 33917809-2 2021 In this work, Li2(BH4)(NH2) is nanoconfined in the mesoporous silica molecule sieve (SBA-15) using a melting-infiltration approach. Amido radical 23-26 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 33917809-2 2021 In this work, Li2(BH4)(NH2) is nanoconfined in the mesoporous silica molecule sieve (SBA-15) using a melting-infiltration approach. mesoporous silica 51-68 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 33917809-2 2021 In this work, Li2(BH4)(NH2) is nanoconfined in the mesoporous silica molecule sieve (SBA-15) using a melting-infiltration approach. sba 85-88 ATP binding cassette subfamily A member 12 Homo sapiens 14-17 33917809-4 2021 In addition, this electrolyte can enable the stable cycling of Li Li2(BH4)(NH2)@SBA-15 TiS2 cells, which exhibit a reversible specific capacity of 150 mAh g-1 with a Coulombic efficiency of 96% after 55 cycles. sapropterin 70-73 ATP binding cassette subfamily A member 12 Homo sapiens 66-69 33917809-4 2021 In addition, this electrolyte can enable the stable cycling of Li Li2(BH4)(NH2)@SBA-15 TiS2 cells, which exhibit a reversible specific capacity of 150 mAh g-1 with a Coulombic efficiency of 96% after 55 cycles. Amido radical 75-78 ATP binding cassette subfamily A member 12 Homo sapiens 66-69 33733754-0 2021 Terahertz Magneto-Optical Excitations of the sd-Hybrid States of Lithium Nitridocobaltate Li2(Li1-xCox)N. We report the results of the experimental and theoretical study of the magnetic anisotropy of single crystals of the Co-doped lithium nitride Li2(Li1-xCox)N with x = 0.005, 0.01, and 0.02. lithium nitridocobaltate 65-89 ATP binding cassette subfamily A member 12 Homo sapiens 90-93 33733754-0 2021 Terahertz Magneto-Optical Excitations of the sd-Hybrid States of Lithium Nitridocobaltate Li2(Li1-xCox)N. We report the results of the experimental and theoretical study of the magnetic anisotropy of single crystals of the Co-doped lithium nitride Li2(Li1-xCox)N with x = 0.005, 0.01, and 0.02. lithium nitridocobaltate 65-89 ATP binding cassette subfamily A member 12 Homo sapiens 248-251 33733754-2 2021 Our combined electron spin resonance (ESR) and THz spectroscopic investigations of Li2(Li1-xCox)N in a very broad frequency range up to 1.7 THz and in magnetic fields up to 16 T enable an accurate determination of the energies of the spin levels of the ground state multiplet S = 1 of the paramagnetic Co(I) ion. thz 140-143 ATP binding cassette subfamily A member 12 Homo sapiens 83-86 33733754-6 2021 Its microscopic origin is the unusual linear coordination of the Co(I) ions in Li2(Li1-xCox)N with two nitrogen ligands. Nitrogen 103-111 ATP binding cassette subfamily A member 12 Homo sapiens 79-82 32602601-0 2021 Effect of Different Temperatures to Remove Reduction Gas on the Photoluminescence Properties of Eu-Doped Li2 (Ba1-x Srx )SiO4 Phosphors. sio4 phosphors 121-135 ATP binding cassette subfamily A member 12 Homo sapiens 105-108 32602601-1 2021 IN THIS STUDY, THE EU-DOPED LI2(BA1-XSRX)SIO4 POWDERS (X=0, 0.2, 0.4, AND 0.6) WERE SYNTHESIZED AT 850OC IN A REDUCTION ATMOSPHERE (5% H2 + 95% N2) FOR A DURATION OF 1 H THROUGH THE SOLID-STATE REACTION METHOD. sio4 41-45 ATP binding cassette subfamily A member 12 Homo sapiens 28-31 32602601-1 2021 IN THIS STUDY, THE EU-DOPED LI2(BA1-XSRX)SIO4 POWDERS (X=0, 0.2, 0.4, AND 0.6) WERE SYNTHESIZED AT 850OC IN A REDUCTION ATMOSPHERE (5% H2 + 95% N2) FOR A DURATION OF 1 H THROUGH THE SOLID-STATE REACTION METHOD. Deuterium 135-137 ATP binding cassette subfamily A member 12 Homo sapiens 28-31 32602601-1 2021 IN THIS STUDY, THE EU-DOPED LI2(BA1-XSRX)SIO4 POWDERS (X=0, 0.2, 0.4, AND 0.6) WERE SYNTHESIZED AT 850OC IN A REDUCTION ATMOSPHERE (5% H2 + 95% N2) FOR A DURATION OF 1 H THROUGH THE SOLID-STATE REACTION METHOD. Nitrogen 144-146 ATP binding cassette subfamily A member 12 Homo sapiens 28-31 32602601-5 2021 EXCEPT THE 800OC-RAR-TREATED LI2BASIO4 PHOSPHOR, PLE SPECTRA OF ALL OTHER LI2(BA1-XSRX)SIO4 PHOSPHORS HAD ONE BROAD EMISSION BAND WITH TWO EMISSION PEAKS CENTERED AT ~242 AND ~283 NM; PL SPECTRA OF THEM HAD ONE BROAD EMISSION BAND WITH ONE EMISSION PEAK CENTERED AT 502~514 NM. 800oc-rar 11-20 ATP binding cassette subfamily A member 12 Homo sapiens 29-32 32602601-6 2021 WE WOULD SHOW THAT THE 800OC-RAR-TREATED LI2BASIO4 PHOSPHOR EMITTED A RED LIGHT AND ALL OTHER LI2(BA1-XSRX)SIO4 PHOSPHORS EMITTED A GREEN LIGHT. sio4 phosphors 107-121 ATP binding cassette subfamily A member 12 Homo sapiens 41-44 32372538-2 2020 However, due to the "shuttle effect" of the highly dissoluble long-chain lithium polyselenides (LPSes, Li 2 Se n , 4 <= n <= 8) in the ether electrolytes and the sluggish one-step solid-solid conversion between Se and Li 2 Se in the carbonate electrolytes, a large amount of porous carbon (> 40 wt% in the electrode) is always needed for the Se cathodes, which seriously counteracts the advantage of Se electrodes in volumetric capacity. lithium polyselenides 73-94 ATP binding cassette subfamily A member 12 Homo sapiens 218-222 32372538-2 2020 However, due to the "shuttle effect" of the highly dissoluble long-chain lithium polyselenides (LPSes, Li 2 Se n , 4 <= n <= 8) in the ether electrolytes and the sluggish one-step solid-solid conversion between Se and Li 2 Se in the carbonate electrolytes, a large amount of porous carbon (> 40 wt% in the electrode) is always needed for the Se cathodes, which seriously counteracts the advantage of Se electrodes in volumetric capacity. Ether 135-140 ATP binding cassette subfamily A member 12 Homo sapiens 103-107 32372538-4 2020 This new Li-Se chemistry not only avoids the "shuttle effect" but also facilitates the conversion between Se and Li 2 Se, enabling an efficient Se cathode with high Se utilization (97%) and enhanced Coulombic efficiency. Selenium 12-14 ATP binding cassette subfamily A member 12 Homo sapiens 113-117 32656883-2 2020 Herein, the Li/electrolyte interface is modified by introducing Li2 S additive to harvest stable all-solid-state lithium metal batteries (LMBs). lithium metal 113-126 ATP binding cassette subfamily A member 12 Homo sapiens 64-67 32656883-3 2020 Cryo-transmission electron microscopy (cryo-TEM) results demonstrate a mosaic interface between poly(ethylene oxide) (PEO) electrolytes and Li metal anodes, in which abundant crystalline grains of Li, Li2 O, LiOH, and Li2 CO3 are randomly distributed. Polyethylene Glycols 118-121 ATP binding cassette subfamily A member 12 Homo sapiens 201-204 32656883-4 2020 Besides, cryo-TEM visualization, combined with molecular dynamics simulations, reveals that the introduction of Li2 S accelerates the decomposition of N(CF3 SO2 )2 - and consequently promotes the formation of abundant LiF nanocrystals in the Li/PEO interface. n(cf3 so2 )2 151-163 ATP binding cassette subfamily A member 12 Homo sapiens 112-115 32656883-4 2020 Besides, cryo-TEM visualization, combined with molecular dynamics simulations, reveals that the introduction of Li2 S accelerates the decomposition of N(CF3 SO2 )2 - and consequently promotes the formation of abundant LiF nanocrystals in the Li/PEO interface. Polyethylene Glycols 245-248 ATP binding cassette subfamily A member 12 Homo sapiens 112-115 33821603-7 2021 An ionic conductivity of 2.96 x 10-2 S cm-1 with an activation energy of 0.23 eV was observed for Li2[B10I10] at 300 C, implying that iodine substitution can improve the ionic conductivity. Iodine 135-141 ATP binding cassette subfamily A member 12 Homo sapiens 98-108 33491840-0 2021 Li-Rich Li2[Ni0.8Co0.1Mn0.1]O2 for Anode-Free Lithium Metal Batteries. lithium metal 46-59 ATP binding cassette subfamily A member 12 Homo sapiens 8-11 31657137-0 2021 Li2 S-Based Li-Ion Sulfur Batteries: Progress and Prospects. Sulfur 19-25 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 31657137-3 2021 Li2 S-based Li-ion sulfur batteries (LISBs), which employ lithium-metal-free anodes, are a convenient and effective way to avoid the use of lithium metal for the realization of practical Li-S batteries. Sulfur 19-25 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 31657137-3 2021 Li2 S-based Li-ion sulfur batteries (LISBs), which employ lithium-metal-free anodes, are a convenient and effective way to avoid the use of lithium metal for the realization of practical Li-S batteries. Lithium 58-65 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 31657137-3 2021 Li2 S-based Li-ion sulfur batteries (LISBs), which employ lithium-metal-free anodes, are a convenient and effective way to avoid the use of lithium metal for the realization of practical Li-S batteries. Lithium 140-147 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 33575255-6 2020 Interestingly, we discovered that the activation of ECE1, ABCA12, BPY2, EEF1A1, RAD9A, and NIPSNAP1 contributed to in vitro resistance to metformin in DU145 and PC3 cell lines. Metformin 138-147 ATP binding cassette subfamily A member 12 Homo sapiens 58-64 33242955-3 2020 While Li2OHCl has a lower conductivity of about 0.1 mS cm-1 at 100 C, its partially fluorinated counterpart, Li2(OH)0.9F0.1Cl, is a significantly better ionic conductor. 1cl 123-126 ATP binding cassette subfamily A member 12 Homo sapiens 6-9 33242955-4 2020 In this article, using density functional theory simulations, we show that it is easier to synthesize Li2OHCl and two of its fluorinated variants, i.e., Li2(OH)0.9F0.1Cl and Li2OHF0.1Cl0.9, than Li3OCl. li2ohf0 174-181 ATP binding cassette subfamily A member 12 Homo sapiens 102-105 33242955-4 2020 In this article, using density functional theory simulations, we show that it is easier to synthesize Li2OHCl and two of its fluorinated variants, i.e., Li2(OH)0.9F0.1Cl and Li2OHF0.1Cl0.9, than Li3OCl. li3ocl 195-201 ATP binding cassette subfamily A member 12 Homo sapiens 102-105 32584489-1 2020 Li2 S holds a promising role as a high-capacity Li-containing cathode, circumventing use of metallic lithium in constructing next-generation batteries to replace current Li-ion batteries. Lithium 101-108 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Metals 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 20-23 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Metals 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Metals 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Metals 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Metals 37-42 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32627911-2 2020 A bidirectional catalyst design, oxide-sulfide heterostructure, is proposed to accelerate both reduction of soluble polysulfides and oxidation of insoluble discharge products (e.g., Li2 S), indicating a fundamental way for improving both the cycling stability and sulfur utilization. Sulfides 39-46 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 32627911-2 2020 A bidirectional catalyst design, oxide-sulfide heterostructure, is proposed to accelerate both reduction of soluble polysulfides and oxidation of insoluble discharge products (e.g., Li2 S), indicating a fundamental way for improving both the cycling stability and sulfur utilization. polysulfide 116-128 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Transition Elements 44-46 ATP binding cassette subfamily A member 12 Homo sapiens 20-23 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Transition Elements 44-46 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32627911-2 2020 A bidirectional catalyst design, oxide-sulfide heterostructure, is proposed to accelerate both reduction of soluble polysulfides and oxidation of insoluble discharge products (e.g., Li2 S), indicating a fundamental way for improving both the cycling stability and sulfur utilization. Sulfur 264-270 ATP binding cassette subfamily A member 12 Homo sapiens 182-185 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Transition Elements 44-46 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Transition Elements 44-46 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32627911-5 2020 For oxidation, TiO2 and Ni3 S2 both show catalytic activity for Li2 S dissolution, refreshing the catalyst surface. titanium dioxide 15-19 ATP binding cassette subfamily A member 12 Homo sapiens 64-67 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Transition Elements 44-46 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Tungsten 267-268 ATP binding cassette subfamily A member 12 Homo sapiens 20-23 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Tungsten 267-268 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32627911-5 2020 For oxidation, TiO2 and Ni3 S2 both show catalytic activity for Li2 S dissolution, refreshing the catalyst surface. ni3 s2 24-30 ATP binding cassette subfamily A member 12 Homo sapiens 64-67 32715639-1 2020 The commercial course of Li-S batteries (LSBs) is impeded by several severe problems, such as low electrical conductivity of S, Li2 S2 , and Li2 S, considerable volume variation up to 80% during multiphase transformation and severe intermediation lithium polysulfides (LiPSs) shuttle effect. Lithium 25-29 ATP binding cassette subfamily A member 12 Homo sapiens 128-131 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Tungsten 267-268 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Tungsten 267-268 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Tungsten 267-268 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Titanium 277-279 ATP binding cassette subfamily A member 12 Homo sapiens 20-23 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Titanium 277-279 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Titanium 277-279 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Titanium 277-279 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. Titanium 277-279 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. polysulfide 369-380 ATP binding cassette subfamily A member 12 Homo sapiens 20-23 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. polysulfide 369-380 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. polysulfide 369-380 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. polysulfide 369-380 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-3 2020 Herein, a series of Li2 S/transition metal (TM) nanocomposites are synthesized via a lithiothermic reduction reaction, and it is realized that the presence of TMs in Li2 S matrix can transform electrochemical behaviors of Li2 S. On the one hand, the incorporation of W, Mo, or Ti greatly increases electronic and ionic conductivity of Li2 S composites and inhibits the polysulfide dissolution via the TM S bond, effectively addressing the drawbacks of Li2 S cathodes. polysulfide 369-380 ATP binding cassette subfamily A member 12 Homo sapiens 166-169 32584489-4 2020 In particular, Li2 S/W and Li2 S/Mo exhibit the highest ionic conductivity of solid-phase Li-ion conductors ever-reported: 5.44 x 10-2 and 3.62 x 10-2 S m-1 , respectively. Tungsten 21-22 ATP binding cassette subfamily A member 12 Homo sapiens 15-18 32584489-5 2020 On the other hand, integrating Co, Mn, and Zn turns Li2 S into a prelithiation agent, forming metal sulfides rather than S8 after the full charge. Cobalt 31-33 ATP binding cassette subfamily A member 12 Homo sapiens 52-55 32584489-5 2020 On the other hand, integrating Co, Mn, and Zn turns Li2 S into a prelithiation agent, forming metal sulfides rather than S8 after the full charge. Zinc 43-45 ATP binding cassette subfamily A member 12 Homo sapiens 52-55 32584489-5 2020 On the other hand, integrating Co, Mn, and Zn turns Li2 S into a prelithiation agent, forming metal sulfides rather than S8 after the full charge. metal sulfides 94-108 ATP binding cassette subfamily A member 12 Homo sapiens 52-55 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. Manganese 41-44 ATP binding cassette subfamily A member 12 Homo sapiens 157-160 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. Manganese 41-44 ATP binding cassette subfamily A member 12 Homo sapiens 170-173 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. manganese oxide 41-47 ATP binding cassette subfamily A member 12 Homo sapiens 157-160 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. manganese oxide 41-47 ATP binding cassette subfamily A member 12 Homo sapiens 170-173 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. o4 45-47 ATP binding cassette subfamily A member 12 Homo sapiens 157-160 32656947-4 2020 In galvanostatic mode, the lithiation of Mn3 O4 undergoes multi-step phase transitions following a reaction pathway of Mn3 O4 + Li+ LiMn3 O4 + Li+ MnO + Li2 O Mn + Li2 O. o4 45-47 ATP binding cassette subfamily A member 12 Homo sapiens 170-173 32656947-6 2020 These results are in sharp contrast to that obtained under a constant-voltage discharge mode, where only a single-step lithiation process of Mn3 O4 + Li+ Mn + Li2 O is observed. manganese oxide 141-147 ATP binding cassette subfamily A member 12 Homo sapiens 161-164 32715639-5 2020 Significantly, Li2 S oxidation process is improved on the FeOOH interlayer determined as a combination of reduced Li2 S decomposition energy barrier and enhanced Li-ion transport. feooh 58-63 ATP binding cassette subfamily A member 12 Homo sapiens 15-18 32715639-5 2020 Significantly, Li2 S oxidation process is improved on the FeOOH interlayer determined as a combination of reduced Li2 S decomposition energy barrier and enhanced Li-ion transport. feooh 58-63 ATP binding cassette subfamily A member 12 Homo sapiens 114-117 32594740-0 2020 Strategies for Enhancing Lithium-Ion Conductivity of Triple-Layered Ruddlesden-Popper Oxides: Case Study of Li2-xLa2-yTi3-zNbzO10. Lithium 25-32 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 32594740-0 2020 Strategies for Enhancing Lithium-Ion Conductivity of Triple-Layered Ruddlesden-Popper Oxides: Case Study of Li2-xLa2-yTi3-zNbzO10. ruddlesden-popper oxides 68-92 ATP binding cassette subfamily A member 12 Homo sapiens 108-111 32343137-2 2020 Here, we report two different approaches for the preparation of heterometallic superoxide complexes [PhL2CrIII-eta1-O2][MX]2 (PhL = -OPh2SiOSiPh2O-, MX+ = [CoCl]+, [ZnBr]+, [ZnCl]+) starting from the CrII precursor complex [PhL2CrII]Li2(THF)4. Superoxides 79-89 ATP binding cassette subfamily A member 12 Homo sapiens 233-242 32432590-0 2020 Li2(Se2O5)(H2O)1.5 CuCl2, a salt-inclusion diselenite structurally based on tetranuclear Li4 complexes. Water 11-14 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 32432590-0 2020 Li2(Se2O5)(H2O)1.5 CuCl2, a salt-inclusion diselenite structurally based on tetranuclear Li4 complexes. cupric chloride 19-24 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 32432590-0 2020 Li2(Se2O5)(H2O)1.5 CuCl2, a salt-inclusion diselenite structurally based on tetranuclear Li4 complexes. diselenite 43-53 ATP binding cassette subfamily A member 12 Homo sapiens 0-3 32361271-0 2020 Garnet-Based All-Ceramic Lithium Battery Enabled by Li2.985B0.005OCl Solder. Lithium 25-32 ATP binding cassette subfamily A member 12 Homo sapiens 52-55 32361271-2 2020 Here, we demonstrate an in situ coated Li2.985B0.005OCl as sintering solder, which is uniformly coated on both LiCoO2 and Li7La3Zr2O12. licoo2 111-117 ATP binding cassette subfamily A member 12 Homo sapiens 39-42 32361271-3 2020 With the low melting point (267 C) and high ionic conductivity (6.8 x 10-5 S cm-1), the Li2.985B0.005OCl solder not only restricts La/Co interdiffusion, but also provides fast Li+ transportation in the cathode. Cobalt 134-136 ATP binding cassette subfamily A member 12 Homo sapiens 88-91 32361271-5 2020 The strain/stress of the LiCoO2 is also released by the small elasticity modulus of Li2.985B0.005OCl, leading to a superior cycling stability. licoo2 25-31 ATP binding cassette subfamily A member 12 Homo sapiens 84-87 32519445-1 2020 Understanding the structural evolution of Li2 S upon operation of lithium-sulfur (Li-S) batteries is inadequate and a complete decomposition of Li2 S during charge is difficult. lithium-sulfur 66-80 ATP binding cassette subfamily A member 12 Homo sapiens 42-45 32519445-1 2020 Understanding the structural evolution of Li2 S upon operation of lithium-sulfur (Li-S) batteries is inadequate and a complete decomposition of Li2 S during charge is difficult. li-s 82-86 ATP binding cassette subfamily A member 12 Homo sapiens 42-45 32519445-7 2020 These results indicate that Li+ ion diffusion in Li2 S dominates its reversibility in the solid-state Li-S batteries. li-s 102-106 ATP binding cassette subfamily A member 12 Homo sapiens 49-52 32343137-2 2020 Here, we report two different approaches for the preparation of heterometallic superoxide complexes [PhL2CrIII-eta1-O2][MX]2 (PhL = -OPh2SiOSiPh2O-, MX+ = [CoCl]+, [ZnBr]+, [ZnCl]+) starting from the CrII precursor complex [PhL2CrII]Li2(THF)4. phl2criii-eta1-o2][mx] 101-123 ATP binding cassette subfamily A member 12 Homo sapiens 233-242 32343137-3 2020 The first strategy proceeds via the exchange of Li+ by [MX]+ through the addition of MX2 to [PhL2CrII]Li2(THF)4 before the reaction with dioxygen, whereas in the second approach a salt metathesis reaction is undertaken after O2 activation by adding MX2 to [PhL2CrIII-eta1-O2]Li2(THF)4. morpholinoanthracycline MX2 85-88 ATP binding cassette subfamily A member 12 Homo sapiens 102-111 32343137-3 2020 The first strategy proceeds via the exchange of Li+ by [MX]+ through the addition of MX2 to [PhL2CrII]Li2(THF)4 before the reaction with dioxygen, whereas in the second approach a salt metathesis reaction is undertaken after O2 activation by adding MX2 to [PhL2CrIII-eta1-O2]Li2(THF)4. Salts 180-184 ATP binding cassette subfamily A member 12 Homo sapiens 275-284 31951131-4 2020 Spe-cifically, the two characteristic features observed in both 27Al and 71Ga NMR spectra result from both the deviations in the poly-hedral coordination/site-symmetry within the 4-fold coordinated Li1/24d sites (rather than the doping of the other Li2/96h or La sites) and with the number of occupied adjacent Li2 sites that share oxygen atoms with these dopant sites. Aluminum 66-68 ATP binding cassette subfamily A member 12 Homo sapiens 249-252 31951131-4 2020 Spe-cifically, the two characteristic features observed in both 27Al and 71Ga NMR spectra result from both the deviations in the poly-hedral coordination/site-symmetry within the 4-fold coordinated Li1/24d sites (rather than the doping of the other Li2/96h or La sites) and with the number of occupied adjacent Li2 sites that share oxygen atoms with these dopant sites. Aluminum 66-68 ATP binding cassette subfamily A member 12 Homo sapiens 311-314 31951131-4 2020 Spe-cifically, the two characteristic features observed in both 27Al and 71Ga NMR spectra result from both the deviations in the poly-hedral coordination/site-symmetry within the 4-fold coordinated Li1/24d sites (rather than the doping of the other Li2/96h or La sites) and with the number of occupied adjacent Li2 sites that share oxygen atoms with these dopant sites. gallium arsenide 73-77 ATP binding cassette subfamily A member 12 Homo sapiens 249-252 31951131-4 2020 Spe-cifically, the two characteristic features observed in both 27Al and 71Ga NMR spectra result from both the deviations in the poly-hedral coordination/site-symmetry within the 4-fold coordinated Li1/24d sites (rather than the doping of the other Li2/96h or La sites) and with the number of occupied adjacent Li2 sites that share oxygen atoms with these dopant sites. gallium arsenide 73-77 ATP binding cassette subfamily A member 12 Homo sapiens 311-314 31825623-4 2020 With the help of certain amounts of H2O (from 100 to 2000 ppm) in the electrolyte, adequate Li2O formed on the lithium anode surface after high current pretreatment, which is necessary for a robust and uniform solid electrolyte interphase (SEI) layer to protect Li metal during the long-term discharge-charge cycling process. Water 36-39 ATP binding cassette subfamily A member 12 Homo sapiens 92-95 31942597-1 2020 Control of the redox potential of lithium terephthalate Li2TP anode material is demonstrated by functionalizing its terephthalate backbone with an electron-donating amino group; this lowers - as intended - the redox potential of Li2TP by 0.14 V. The two Li-organic electrode materials, Li2TP and Li2TP-NH2, are fabricated as crystalline thin films from gaseous precursors using the atomic/molecular layer deposition (ALD/MLD) technique. terephthalic acid 42-55 ATP binding cassette subfamily A member 12 Homo sapiens 56-59 31942597-1 2020 Control of the redox potential of lithium terephthalate Li2TP anode material is demonstrated by functionalizing its terephthalate backbone with an electron-donating amino group; this lowers - as intended - the redox potential of Li2TP by 0.14 V. The two Li-organic electrode materials, Li2TP and Li2TP-NH2, are fabricated as crystalline thin films from gaseous precursors using the atomic/molecular layer deposition (ALD/MLD) technique. Amino Acids 165-170 ATP binding cassette subfamily A member 12 Homo sapiens 56-59 31942597-1 2020 Control of the redox potential of lithium terephthalate Li2TP anode material is demonstrated by functionalizing its terephthalate backbone with an electron-donating amino group; this lowers - as intended - the redox potential of Li2TP by 0.14 V. The two Li-organic electrode materials, Li2TP and Li2TP-NH2, are fabricated as crystalline thin films from gaseous precursors using the atomic/molecular layer deposition (ALD/MLD) technique. Lithium 229-234 ATP binding cassette subfamily A member 12 Homo sapiens 56-59 31942597-1 2020 Control of the redox potential of lithium terephthalate Li2TP anode material is demonstrated by functionalizing its terephthalate backbone with an electron-donating amino group; this lowers - as intended - the redox potential of Li2TP by 0.14 V. The two Li-organic electrode materials, Li2TP and Li2TP-NH2, are fabricated as crystalline thin films from gaseous precursors using the atomic/molecular layer deposition (ALD/MLD) technique. Lithium 296-305 ATP binding cassette subfamily A member 12 Homo sapiens 56-59 31825623-4 2020 With the help of certain amounts of H2O (from 100 to 2000 ppm) in the electrolyte, adequate Li2O formed on the lithium anode surface after high current pretreatment, which is necessary for a robust and uniform solid electrolyte interphase (SEI) layer to protect Li metal during the long-term discharge-charge cycling process. Lithium 111-118 ATP binding cassette subfamily A member 12 Homo sapiens 92-95 31721414-0 2019 Advanced Li2 S/Si Full Battery Enabled by TiN Polysulfide Immobilizer. Silicon 15-17 ATP binding cassette subfamily A member 12 Homo sapiens 9-12 31721414-0 2019 Advanced Li2 S/Si Full Battery Enabled by TiN Polysulfide Immobilizer. polysulfide 46-57 ATP binding cassette subfamily A member 12 Homo sapiens 9-12 31721414-0 2019 Advanced Li2 S/Si Full Battery Enabled by TiN Polysulfide Immobilizer. titanium nitride 42-45 ATP binding cassette subfamily A member 12 Homo sapiens 9-12 31721414-1 2019 Lithium sulfide (Li2 S) is a promising cathode material with high capacity, which can be paired with nonlithium metal anodes such as silicon or tin so that the safety issues caused by the Li anode can be effectively avoided. lithium sulfide 0-15 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 31721414-1 2019 Lithium sulfide (Li2 S) is a promising cathode material with high capacity, which can be paired with nonlithium metal anodes such as silicon or tin so that the safety issues caused by the Li anode can be effectively avoided. nonlithium 101-111 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 31721414-1 2019 Lithium sulfide (Li2 S) is a promising cathode material with high capacity, which can be paired with nonlithium metal anodes such as silicon or tin so that the safety issues caused by the Li anode can be effectively avoided. Silicon 133-140 ATP binding cassette subfamily A member 12 Homo sapiens 17-20 31721414-2 2019 However, the Li2 S full cell suffers from rapid capacity degradation due to the dissolution of intermediate polysulfides. polysulfide 108-120 ATP binding cassette subfamily A member 12 Homo sapiens 13-16 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). Silicon 16-18 ATP binding cassette subfamily A member 12 Homo sapiens 10-13 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). Silicon 16-18 ATP binding cassette subfamily A member 12 Homo sapiens 48-51 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). titanium nitride 78-94 ATP binding cassette subfamily A member 12 Homo sapiens 10-13 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). titanium nitride 96-99 ATP binding cassette subfamily A member 12 Homo sapiens 10-13 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). polysulfide 101-112 ATP binding cassette subfamily A member 12 Homo sapiens 10-13 31721414-3 2019 Herein, a Li2 S/Si full cell is designed with a Li2 S cathode incorporated by titanium nitride (TiN) polysulfide immobilizer within parallel hollow carbon (PHC). Carbon 148-154 ATP binding cassette subfamily A member 12 Homo sapiens 10-13 31756047-5 2019 Both experimental and theoretical calculation results suggest that a new catalytic interface enabled by metal-like NbN with superb electrocatalysis anchored on NG is highly effective in regulating the blocked polysulfide redox reaction and tailoring the Li2 S nucleation-growth-decomposition process. Niobium 115-118 ATP binding cassette subfamily A member 12 Homo sapiens 254-257 31756047-5 2019 Both experimental and theoretical calculation results suggest that a new catalytic interface enabled by metal-like NbN with superb electrocatalysis anchored on NG is highly effective in regulating the blocked polysulfide redox reaction and tailoring the Li2 S nucleation-growth-decomposition process. polysulfide 209-220 ATP binding cassette subfamily A member 12 Homo sapiens 254-257 31429162-6 2019 Thanks to a reversible electrochemical activity located at an average potential of 2.2 V vs. Li+ /Li, the coupling with dilithium 2,5-(dianilino)terephthalate (Li2 DAnT) as the positive electrode enabled the fabrication of the first all-organic anionic rechargeable batteries based on crystallized host electrode materials capable of delivering a specific capacity of 27 mAh/gelectrodes with a stable cycling over dozens of cycles ( 24 Wh/kgelectrodes ). dilithium 2,5-(dianilino)terephthalate 120-158 ATP binding cassette subfamily A member 12 Homo sapiens 160-163 31429193-4 2019 In comparison, the low electronic conductivity and strong adsorption strength of VO2 increased Li+ diffusion as well as Li2 S decomposition barriers of the electrode, resulting in relatively poor rate capability and cycle stability. vo2 81-84 ATP binding cassette subfamily A member 12 Homo sapiens 120-123 31601812-4 2019 According to the developed mechanism-based analytical model, we demonstrate that sulfur utilization is limited by the solubility of lithium-polysulfides and further conversion from lithium-polysulfides to Li2S is limited by the electronically accessible surface area of the carbon matrix. Sulfur 81-87 ATP binding cassette subfamily A member 12 Homo sapiens 205-208 31601812-4 2019 According to the developed mechanism-based analytical model, we demonstrate that sulfur utilization is limited by the solubility of lithium-polysulfides and further conversion from lithium-polysulfides to Li2S is limited by the electronically accessible surface area of the carbon matrix. polysulfide 181-201 ATP binding cassette subfamily A member 12 Homo sapiens 205-208 31601812-4 2019 According to the developed mechanism-based analytical model, we demonstrate that sulfur utilization is limited by the solubility of lithium-polysulfides and further conversion from lithium-polysulfides to Li2S is limited by the electronically accessible surface area of the carbon matrix. Carbon 274-280 ATP binding cassette subfamily A member 12 Homo sapiens 205-208