PMID-sentid Pub_year Sent_text comp_official_name comp_offset protein_name organism prot_offset 32964599-4 2021 Here, as a proof-of-concept, we presented a combination of theoretical and experimental investigation to certify that nickel diphosphide phase-junction (c-NiP 2 /m-NiP2 ) is an effective electrocatalyst for hydrogen production in alkaline media. nickel diphosphide 118-136 BCL2 interacting protein 2 Homo sapiens 164-168 32964599-4 2021 Here, as a proof-of-concept, we presented a combination of theoretical and experimental investigation to certify that nickel diphosphide phase-junction (c-NiP 2 /m-NiP2 ) is an effective electrocatalyst for hydrogen production in alkaline media. Hydrogen 207-215 BCL2 interacting protein 2 Homo sapiens 164-168 32964599-5 2021 The overpotential (at 10 mA cm -2 ) for NiP2-650 (c/m ) in alkaline media could be significantly reduced by 26% and 96% compared with c-NiP2 and m-NiP2 , respectively. alkaline media 59-73 BCL2 interacting protein 2 Homo sapiens 40-44 32789168-6 2020 Upon nocodazole-induced microtubule disassembly, the interaction between BNIP-2 and GEF-H1 increases, while knockdown of BNIP-2 reduces RhoA activation and cell rounding via uncoupling RhoA-GEF-H1 interaction. Nocodazole 5-15 BCL2 interacting protein 2 Homo sapiens 73-79 32787258-1 2020 A photochemically crushable and regenerative metal-organic framework (DTEMOF) was developed by complexation of photochromic ligand PyDTEopen and 5-nitroisophthalate (nip2-) with Cd2+ in DMF/MeOH. Metals 45-50 BCL2 interacting protein 2 Homo sapiens 166-170 32787258-1 2020 A photochemically crushable and regenerative metal-organic framework (DTEMOF) was developed by complexation of photochromic ligand PyDTEopen and 5-nitroisophthalate (nip2-) with Cd2+ in DMF/MeOH. 5-nitroisophthalic acid 145-164 BCL2 interacting protein 2 Homo sapiens 166-170 32787258-1 2020 A photochemically crushable and regenerative metal-organic framework (DTEMOF) was developed by complexation of photochromic ligand PyDTEopen and 5-nitroisophthalate (nip2-) with Cd2+ in DMF/MeOH. Dimethylformamide 186-189 BCL2 interacting protein 2 Homo sapiens 166-170 32787258-1 2020 A photochemically crushable and regenerative metal-organic framework (DTEMOF) was developed by complexation of photochromic ligand PyDTEopen and 5-nitroisophthalate (nip2-) with Cd2+ in DMF/MeOH. Methanol 190-194 BCL2 interacting protein 2 Homo sapiens 166-170 32789168-6 2020 Upon nocodazole-induced microtubule disassembly, the interaction between BNIP-2 and GEF-H1 increases, while knockdown of BNIP-2 reduces RhoA activation and cell rounding via uncoupling RhoA-GEF-H1 interaction. Nocodazole 5-15 BCL2 interacting protein 2 Homo sapiens 121-127 31841300-2 2020 Herein, we report a unique bimetallic diphosphide pair (FeP2-NiP2) forming spherical nanocages encapsulated in P-doped carbon layers (FeP2-NiP2@PC) as advanced bifunctional electrocatalyst synthesized by a very facile phosphorization approach. diphosphide 38-49 BCL2 interacting protein 2 Homo sapiens 61-65 31841300-2 2020 Herein, we report a unique bimetallic diphosphide pair (FeP2-NiP2) forming spherical nanocages encapsulated in P-doped carbon layers (FeP2-NiP2@PC) as advanced bifunctional electrocatalyst synthesized by a very facile phosphorization approach. diphosphide 38-49 BCL2 interacting protein 2 Homo sapiens 139-143 31841300-2 2020 Herein, we report a unique bimetallic diphosphide pair (FeP2-NiP2) forming spherical nanocages encapsulated in P-doped carbon layers (FeP2-NiP2@PC) as advanced bifunctional electrocatalyst synthesized by a very facile phosphorization approach. Carbon 119-125 BCL2 interacting protein 2 Homo sapiens 61-65 31841300-2 2020 Herein, we report a unique bimetallic diphosphide pair (FeP2-NiP2) forming spherical nanocages encapsulated in P-doped carbon layers (FeP2-NiP2@PC) as advanced bifunctional electrocatalyst synthesized by a very facile phosphorization approach. Carbon 119-125 BCL2 interacting protein 2 Homo sapiens 139-143 31841300-3 2020 The obtained FeP2-NiP2@PC electrocatalyst exhibits an outstanding OER activity with an ultralow overpotential of 248 mV in 1 M KOH and a low overpotential of 117 mV for HER in 0.5 M H2SO4 (@10 mA cm-2). ERBB2 protein, human 169-172 BCL2 interacting protein 2 Homo sapiens 18-22 31841300-3 2020 The obtained FeP2-NiP2@PC electrocatalyst exhibits an outstanding OER activity with an ultralow overpotential of 248 mV in 1 M KOH and a low overpotential of 117 mV for HER in 0.5 M H2SO4 (@10 mA cm-2). bis-(3-(3',5'-di-tert-butyl-4'-hydroxyphenyl)propyl)sulfide 182-187 BCL2 interacting protein 2 Homo sapiens 18-22 31841300-6 2020 Further investigation unveils that the electrochemical activation process boosts in-situ phase transformation of phosphides and oxides to oxyhydroxides as the vital intermediates in FeP2-NiP2@PC during OER electrocatalysis. zinc phosphide 113-123 BCL2 interacting protein 2 Homo sapiens 187-191 31841300-6 2020 Further investigation unveils that the electrochemical activation process boosts in-situ phase transformation of phosphides and oxides to oxyhydroxides as the vital intermediates in FeP2-NiP2@PC during OER electrocatalysis. Oxides 128-134 BCL2 interacting protein 2 Homo sapiens 187-191 31841300-6 2020 Further investigation unveils that the electrochemical activation process boosts in-situ phase transformation of phosphides and oxides to oxyhydroxides as the vital intermediates in FeP2-NiP2@PC during OER electrocatalysis. ferric hydroxide 138-151 BCL2 interacting protein 2 Homo sapiens 187-191 29741363-4 2018 In this new catalytic system, oxygen-vacancy-rich NiO provides abundant active sites for dissociation of water, and the negatively charged P species in NiP2 facilitate adsorption of hydrogen intermediates. Hydrogen 182-190 BCL2 interacting protein 2 Homo sapiens 152-156 31922001-4 2020 To this end, we used N-induced lattice contraction to generally boost the HER catalysis of P-rich TMPs including CoP2, FeP2, NiP2, and MoP2. Nitrogen 21-22 BCL2 interacting protein 2 Homo sapiens 125-129 30901203-4 2019 The facile synthesis of FeP2, CoP3, NiP2, and CuP2 is thermochemically driven by PCl3 formation from reactions of anhydrous metal halides and P4 vapor at 500 C. Well-crystallized micrometer-sized particles result from these solvent-free reactions. metal halides 124-137 BCL2 interacting protein 2 Homo sapiens 36-40 30901203-5 2019 A tin flux leads to more complete reactions at lower temperature for FeP2 and enables synthesis of a monoclinic polymorph of NiP2 rather than the kinetic cubic product formed by direct reaction. Tin 2-5 BCL2 interacting protein 2 Homo sapiens 125-129 30901203-8 2019 The catalytic activity for hydrogen evolution ordered by higher current at a fixed electrode geometric area and low onset potential is CoP3 > NiP2 (cubic and monoclinic) > FeP2 >> CuP2. Hydrogen 27-35 BCL2 interacting protein 2 Homo sapiens 145-149 30836002-3 2019 In this work, we systematically compare the electrochemical behavior of a variety of polyphosphides bulks, discovering that the CuP2 bulks have higher initial reversible capacity (416 mAh g-1 at 0.1 A g-1) and CE (74%) compared to the FeP2, CoP3, and NiP2 bulks, which is related to the unique crystal structure of CuP2. polyphosphides 85-99 BCL2 interacting protein 2 Homo sapiens 251-255 30836002-3 2019 In this work, we systematically compare the electrochemical behavior of a variety of polyphosphides bulks, discovering that the CuP2 bulks have higher initial reversible capacity (416 mAh g-1 at 0.1 A g-1) and CE (74%) compared to the FeP2, CoP3, and NiP2 bulks, which is related to the unique crystal structure of CuP2. cup2 128-132 BCL2 interacting protein 2 Homo sapiens 251-255 30285280-3 2018 Here, 6 nm wall-thick Ni2 P-NiP2 hollow nanoparticle polymorphs combining metallic Ni2 P and metalloid NiP2 with observable heterointerfaces are synthesized. ni2 p 22-27 BCL2 interacting protein 2 Homo sapiens 28-32 30285280-3 2018 Here, 6 nm wall-thick Ni2 P-NiP2 hollow nanoparticle polymorphs combining metallic Ni2 P and metalloid NiP2 with observable heterointerfaces are synthesized. ni2 p 22-27 BCL2 interacting protein 2 Homo sapiens 103-107 30285280-6 2018 That is, the heterojunctions balance the metallic Ni2 P and the metalloid NiP2 to form an optimized phosphide polymorph catalyst for the HER. phosphide(3-) 100-109 BCL2 interacting protein 2 Homo sapiens 74-78 29741363-0 2018 Designing Hybrid NiP2/NiO Nanorod Arrays for Efficient Alkaline Hydrogen Evolution. Hydrogen 64-72 BCL2 interacting protein 2 Homo sapiens 17-21 29741363-4 2018 In this new catalytic system, oxygen-vacancy-rich NiO provides abundant active sites for dissociation of water, and the negatively charged P species in NiP2 facilitate adsorption of hydrogen intermediates. Oxygen 30-36 BCL2 interacting protein 2 Homo sapiens 152-156 26238550-0 2015 Effect of Synthetic Levers on Nickel Phosphide Nanoparticle Formation: Ni5P4 and NiP2. nickel phosphide 30-46 BCL2 interacting protein 2 Homo sapiens 81-85 27768279-0 2016 Efficient Photoelectrochemical Hydrogen Evolution on Silicon Photocathodes Interfaced with Nanostructured NiP2 Cocatalyst Films. Hydrogen 31-39 BCL2 interacting protein 2 Homo sapiens 106-110 27768279-0 2016 Efficient Photoelectrochemical Hydrogen Evolution on Silicon Photocathodes Interfaced with Nanostructured NiP2 Cocatalyst Films. Silicon 53-60 BCL2 interacting protein 2 Homo sapiens 106-110 27768279-4 2016 In this study, we directly grow nanostructured pyrite-phase nickel phosphide (NiP2) cocatalyst films on textured pn+-Si photocathodes via on-surface reaction at high temperatures. nickel phosphide 60-76 BCL2 interacting protein 2 Homo sapiens 78-82 27768279-4 2016 In this study, we directly grow nanostructured pyrite-phase nickel phosphide (NiP2) cocatalyst films on textured pn+-Si photocathodes via on-surface reaction at high temperatures. cocatalyst 84-94 BCL2 interacting protein 2 Homo sapiens 78-82 27768279-4 2016 In this study, we directly grow nanostructured pyrite-phase nickel phosphide (NiP2) cocatalyst films on textured pn+-Si photocathodes via on-surface reaction at high temperatures. 1,2-diaminopropane 113-116 BCL2 interacting protein 2 Homo sapiens 78-82 27768279-4 2016 In this study, we directly grow nanostructured pyrite-phase nickel phosphide (NiP2) cocatalyst films on textured pn+-Si photocathodes via on-surface reaction at high temperatures. Silicon 117-119 BCL2 interacting protein 2 Homo sapiens 78-82 27768279-6 2016 As a result, our pn+-Si/Ti/NiP2 photocathodes demonstrate a great PEC onset potential of 0.41 V versus reversible hydrogen electrode (RHE), a decent photocurrent density of ~12 mA/cm2 at the thermodynamic potential of hydrogen evolution, and an impressive operation durability for at least 6 h in 0.5 M H2SO4. Hydrogen 114-122 BCL2 interacting protein 2 Homo sapiens 27-31 27768279-6 2016 As a result, our pn+-Si/Ti/NiP2 photocathodes demonstrate a great PEC onset potential of 0.41 V versus reversible hydrogen electrode (RHE), a decent photocurrent density of ~12 mA/cm2 at the thermodynamic potential of hydrogen evolution, and an impressive operation durability for at least 6 h in 0.5 M H2SO4. Hydrogen 218-226 BCL2 interacting protein 2 Homo sapiens 27-31 27768279-6 2016 As a result, our pn+-Si/Ti/NiP2 photocathodes demonstrate a great PEC onset potential of 0.41 V versus reversible hydrogen electrode (RHE), a decent photocurrent density of ~12 mA/cm2 at the thermodynamic potential of hydrogen evolution, and an impressive operation durability for at least 6 h in 0.5 M H2SO4. sulfuric acid 303-308 BCL2 interacting protein 2 Homo sapiens 27-31 28544389-2 2017 A unique ball-cactus-like microsphere of carbon coated NiP2 /Ni3 Sn4 with deep-rooted carbon nanotubes (Ni-Sn-P@C-CNT) is demonstrated in this work to solve this problem. Carbon 41-47 BCL2 interacting protein 2 Homo sapiens 55-59 28544389-2 2017 A unique ball-cactus-like microsphere of carbon coated NiP2 /Ni3 Sn4 with deep-rooted carbon nanotubes (Ni-Sn-P@C-CNT) is demonstrated in this work to solve this problem. Carbon 86-92 BCL2 interacting protein 2 Homo sapiens 55-59 28544389-2 2017 A unique ball-cactus-like microsphere of carbon coated NiP2 /Ni3 Sn4 with deep-rooted carbon nanotubes (Ni-Sn-P@C-CNT) is demonstrated in this work to solve this problem. ni-sn-p 104-111 BCL2 interacting protein 2 Homo sapiens 55-59 28544389-2 2017 A unique ball-cactus-like microsphere of carbon coated NiP2 /Ni3 Sn4 with deep-rooted carbon nanotubes (Ni-Sn-P@C-CNT) is demonstrated in this work to solve this problem. Carbon 112-113 BCL2 interacting protein 2 Homo sapiens 55-59 28323408-0 2017 Monodispersed Carbon-Coated Cubic NiP2 Nanoparticles Anchored on Carbon Nanotubes as Ultra-Long-Life Anodes for Reversible Lithium Storage. Carbon 14-20 BCL2 interacting protein 2 Homo sapiens 34-38 28323408-0 2017 Monodispersed Carbon-Coated Cubic NiP2 Nanoparticles Anchored on Carbon Nanotubes as Ultra-Long-Life Anodes for Reversible Lithium Storage. Carbon 65-71 BCL2 interacting protein 2 Homo sapiens 34-38 28323408-0 2017 Monodispersed Carbon-Coated Cubic NiP2 Nanoparticles Anchored on Carbon Nanotubes as Ultra-Long-Life Anodes for Reversible Lithium Storage. Lithium 123-130 BCL2 interacting protein 2 Homo sapiens 34-38 28323408-5 2017 Monodispersed carbon-coated cubic NiP2 nanoparticles anchored on carbon nanotubes (NiP2@C-CNTs) as a proof-of-concept were designed and synthesized. Carbon 14-20 BCL2 interacting protein 2 Homo sapiens 34-38 28323408-5 2017 Monodispersed carbon-coated cubic NiP2 nanoparticles anchored on carbon nanotubes (NiP2@C-CNTs) as a proof-of-concept were designed and synthesized. Carbon 14-20 BCL2 interacting protein 2 Homo sapiens 83-87 28323408-5 2017 Monodispersed carbon-coated cubic NiP2 nanoparticles anchored on carbon nanotubes (NiP2@C-CNTs) as a proof-of-concept were designed and synthesized. Carbon 65-71 BCL2 interacting protein 2 Homo sapiens 34-38 26238550-1 2015 Due to their unique catalytic, electronic, and redox processes, Ni5P4 and NiP2 nanoparticles are of interest for a wide-range of applications from the hydrogen evolution reaction to energy storage (batteries); yet synthetic approaches to these materials are limited. Hydrogen 151-159 BCL2 interacting protein 2 Homo sapiens 74-78 26238550-2 2015 In the present work, a phase-control strategy enabling the arrested-precipitation synthesis of nanoparticles of Ni5P4 and NiP2 as phase-pure samples using different Ni organometallic precursors and trioctylphosphine (TOP) is described. TRIOCTYLPHOSPHINE 198-215 BCL2 interacting protein 2 Homo sapiens 122-126 26238550-4 2015 Notably, the 230 C intermediate step favors the ultimate formation of Ni2P and hinders further phosphidation to form Ni5P4 or NiP2 as phase-pure products. ni2p 71-75 BCL2 interacting protein 2 Homo sapiens 127-131 25667163-4 2015 Seven minerals from the ternary Fe-Ni-P system have been identified with five of them, NiP2, Ni5P4, Ni2P, FeP and FeP2, previously unknown in nature. fe-ni-p 32-39 BCL2 interacting protein 2 Homo sapiens 87-91 24568676-7 2014 In contrast, phosphorus-rich phosphide NiP2 is formed on Ni/CNTs and NiO/CNTs. Phosphorus 13-23 BCL2 interacting protein 2 Homo sapiens 39-43 25472445-6 2015 The CRAL-TRIO domain of BNIP-2 specifically interacts with phosphatidylserine, and the vesicular localization of BNIP-2 requires interaction with this phospholipid. Phospholipids 151-163 BCL2 interacting protein 2 Homo sapiens 24-30 25472445-6 2015 The CRAL-TRIO domain of BNIP-2 specifically interacts with phosphatidylserine, and the vesicular localization of BNIP-2 requires interaction with this phospholipid. Phospholipids 151-163 BCL2 interacting protein 2 Homo sapiens 113-119 25293654-0 2014 NiP2 nanosheet arrays supported on carbon cloth: an efficient 3D hydrogen evolution cathode in both acidic and alkaline solutions. Carbon 35-41 BCL2 interacting protein 2 Homo sapiens 0-4 25293654-0 2014 NiP2 nanosheet arrays supported on carbon cloth: an efficient 3D hydrogen evolution cathode in both acidic and alkaline solutions. Hydrogen 65-73 BCL2 interacting protein 2 Homo sapiens 0-4 25293654-2 2014 In this communication, we develop a two-step strategy for constructing NiP2 nanosheet arrays on carbon cloth (NiP2 NS/CC). Carbon 96-102 BCL2 interacting protein 2 Homo sapiens 71-75 25293654-2 2014 In this communication, we develop a two-step strategy for constructing NiP2 nanosheet arrays on carbon cloth (NiP2 NS/CC). Carbon 96-102 BCL2 interacting protein 2 Homo sapiens 110-114 25293654-3 2014 As a novel 3D hydrogen evolution cathode, the NiP2 NS/CC electrode is highly active in acidic solutions and needs an overpotential of 75 and 204 mV to achieve current densities of 10 and 100 mA cm(-2), respectively, and it preserves its catalytic activity for at least 57 h. Moreover, it also operates efficiently under alkaline conditions. Hydrogen 14-22 BCL2 interacting protein 2 Homo sapiens 46-50 34901657-0 2021 Trace Amount of NiP2 Cooperative CoMoP Nanosheets Inducing Efficient Hydrogen Evolution. Hydrogen 69-77 BCL2 interacting protein 2 Homo sapiens 16-20 22026405-1 2011 Two novel photochromic naphthopyrans containing naphthalimide moieties (Nip1 and Nip2) were studied in solution under flash photolysis conditions, exhibiting highly photochromic response, rapid thermal bleaching rate and good fatigue-resistance. naphthopyrans 23-36 BCL2 interacting protein 2 Homo sapiens 81-85 22026405-1 2011 Two novel photochromic naphthopyrans containing naphthalimide moieties (Nip1 and Nip2) were studied in solution under flash photolysis conditions, exhibiting highly photochromic response, rapid thermal bleaching rate and good fatigue-resistance. Naphthalimides 48-61 BCL2 interacting protein 2 Homo sapiens 81-85 22026405-2 2011 Owing to the different N-substituted imide groups at the naphthalimide units, the thermal bleaching rate of Nip2 bearing phenyl on the naphthalimide unit is found to be approximately 2 times that of Nip1 bearing n-butyl, indicating that the photochromic properties can be modulated with introduction of different functional groups on the naphthalimide unit. Nitrogen 23-24 BCL2 interacting protein 2 Homo sapiens 108-112 22026405-2 2011 Owing to the different N-substituted imide groups at the naphthalimide units, the thermal bleaching rate of Nip2 bearing phenyl on the naphthalimide unit is found to be approximately 2 times that of Nip1 bearing n-butyl, indicating that the photochromic properties can be modulated with introduction of different functional groups on the naphthalimide unit. Naphthalimides 57-70 BCL2 interacting protein 2 Homo sapiens 108-112 22026405-2 2011 Owing to the different N-substituted imide groups at the naphthalimide units, the thermal bleaching rate of Nip2 bearing phenyl on the naphthalimide unit is found to be approximately 2 times that of Nip1 bearing n-butyl, indicating that the photochromic properties can be modulated with introduction of different functional groups on the naphthalimide unit. Naphthalimides 135-148 BCL2 interacting protein 2 Homo sapiens 108-112 22026405-2 2011 Owing to the different N-substituted imide groups at the naphthalimide units, the thermal bleaching rate of Nip2 bearing phenyl on the naphthalimide unit is found to be approximately 2 times that of Nip1 bearing n-butyl, indicating that the photochromic properties can be modulated with introduction of different functional groups on the naphthalimide unit. n-butyl 212-219 BCL2 interacting protein 2 Homo sapiens 108-112 22026405-2 2011 Owing to the different N-substituted imide groups at the naphthalimide units, the thermal bleaching rate of Nip2 bearing phenyl on the naphthalimide unit is found to be approximately 2 times that of Nip1 bearing n-butyl, indicating that the photochromic properties can be modulated with introduction of different functional groups on the naphthalimide unit. Naphthalimides 135-148 BCL2 interacting protein 2 Homo sapiens 108-112 22026405-3 2011 In Nip1 and Nip2, the strong electron-withdrawing effect of the imide group incorporated at the naphthalimide moiety maintains several merits: (i) shifting absorption bands to longer wavelength, (ii) beneficial to an enhancement in the ratio of transoid-cis (TC) isomer and an increase in the transformation rate from transoid-trans (TT) to TC with respect to reference compound NP, and (iii) resulting in a preferable color bleaching rate and fading absolutely to their colorless state with thermal reversibility. Naphthalimides 96-109 BCL2 interacting protein 2 Homo sapiens 12-16 22026405-3 2011 In Nip1 and Nip2, the strong electron-withdrawing effect of the imide group incorporated at the naphthalimide moiety maintains several merits: (i) shifting absorption bands to longer wavelength, (ii) beneficial to an enhancement in the ratio of transoid-cis (TC) isomer and an increase in the transformation rate from transoid-trans (TT) to TC with respect to reference compound NP, and (iii) resulting in a preferable color bleaching rate and fading absolutely to their colorless state with thermal reversibility. Technetium 259-261 BCL2 interacting protein 2 Homo sapiens 12-16 15506981-6 2004 BPGAP1 is a novel RhoGAP that co-ordinately regulates pseudopodia and cell migration through the interplay of its BNIP-2 and Cdc42GAP homology domains serving as a homophilic/heterophilic interaction device, an enzymic RhoGAP domain that inactivates RhoA and a proline-rich region that binds the Src homology-3 domain of cortactin. Proline 261-268 BCL2 interacting protein 2 Homo sapiens 114-120 11744098-3 2001 Among these messages we focused our attention on bnip2, which expression was inhibited by estradiol. Estradiol 90-99 BCL2 interacting protein 2 Homo sapiens 49-54 10799524-2 2000 BNIP-2 contains many arginine residues at the carboxyl terminus, which includes the region of homology to the noncatalytic domain of Cdc42GAP, termed BNIP-2 and Cdc42GAP homology (BCH) domain. Arginine 21-29 BCL2 interacting protein 2 Homo sapiens 0-6 10551883-0 1999 Tyrosine phosphorylation of the Bcl-2-associated protein BNIP-2 by fibroblast growth factor receptor-1 prevents its binding to Cdc42GAP and Cdc42. Tyrosine 0-8 BCL2 interacting protein 2 Homo sapiens 57-63 10551883-4 1999 When cotransfected in 293T cells, BNIP-2 was tyrosine-phosphorylated via Flg, but their interaction was transient and could only be seen by "capture" experiments with catalytically inert kinase mutants. Tyrosine 45-53 BCL2 interacting protein 2 Homo sapiens 34-40 10551883-5 1999 When responsive cells were challenged with basic FGF, endogenous tyrosine-phosphorylated BNIP-2 could be precipitated with a BNIP-2 antibody. Tyrosine 65-73 BCL2 interacting protein 2 Homo sapiens 89-95 10551883-5 1999 When responsive cells were challenged with basic FGF, endogenous tyrosine-phosphorylated BNIP-2 could be precipitated with a BNIP-2 antibody. Tyrosine 65-73 BCL2 interacting protein 2 Homo sapiens 125-131 10551883-7 1999 BNIP-2 shares a region of homology with the noncatalytic domain of Cdc42GAP, a GTPase-activating protein for the small GTP-binding molecule, Cdc42. Guanosine Triphosphate 79-82 BCL2 interacting protein 2 Homo sapiens 0-6 10551883-10 1999 In all cases, tyrosine phosphorylation of BNIP-2 severely impaired its association with Cdc42GAP and its induced GTPase-activating protein-like activity toward Cdc42. Tyrosine 14-22 BCL2 interacting protein 2 Homo sapiens 42-48 10954711-3 2000 Despite the lack of obvious homology to any known catalytic domains of GTPase-activating proteins (GAPs), the BCH domain of BNIP-2 bound Cdc42 and stimulated the GTPase activity via a novel arginine-patch motif similar to that employed by one contributing partner in a Cdc42 homodimer. Arginine 190-198 BCL2 interacting protein 2 Homo sapiens 124-130 10799524-8 2000 From deletion studies, a region adjacent to the arginine patch ((288)EYV(290) on BNIP-2) and the Switch I and Rho family-specific "Insert" region on Cdc42 are involved in the binding. Arginine 48-56 BCL2 interacting protein 2 Homo sapiens 81-87 10799524-9 2000 The results indicate that the BCH domain of BNIP-2 represents a novel GAP domain that employs an arginine patch motif similar to that of the Cdc42-homodimer. Arginine 97-105 BCL2 interacting protein 2 Homo sapiens 44-50 21699173-0 2011 A 3D Cu(II) coordination framework with mu4-/mu2-oxalato anions and a bent dipyridyl coligand: unique zeolite-type NiP2 topological network and magnetic properties. cu(ii) 5-11 BCL2 interacting protein 2 Homo sapiens 115-119 34825490-1 2022 The catalytic hydrogen-evolving activities of transition-metal phosphides are greatly related to the phosphorus content, but the physical origin of performance enhancement remains ambiguous, and tuning the catalytic activity of nickel phosphides (NiP2 /Ni5 P4 ) remains challenging due to unfavorable H* adsorption. Hydrogen 14-22 BCL2 interacting protein 2 Homo sapiens 247-251 34825490-1 2022 The catalytic hydrogen-evolving activities of transition-metal phosphides are greatly related to the phosphorus content, but the physical origin of performance enhancement remains ambiguous, and tuning the catalytic activity of nickel phosphides (NiP2 /Ni5 P4 ) remains challenging due to unfavorable H* adsorption. transition-metal phosphides 46-73 BCL2 interacting protein 2 Homo sapiens 247-251 34825490-1 2022 The catalytic hydrogen-evolving activities of transition-metal phosphides are greatly related to the phosphorus content, but the physical origin of performance enhancement remains ambiguous, and tuning the catalytic activity of nickel phosphides (NiP2 /Ni5 P4 ) remains challenging due to unfavorable H* adsorption. Phosphorus 101-111 BCL2 interacting protein 2 Homo sapiens 247-251 34825490-1 2022 The catalytic hydrogen-evolving activities of transition-metal phosphides are greatly related to the phosphorus content, but the physical origin of performance enhancement remains ambiguous, and tuning the catalytic activity of nickel phosphides (NiP2 /Ni5 P4 ) remains challenging due to unfavorable H* adsorption. nickel phosphides 228-245 BCL2 interacting protein 2 Homo sapiens 247-251 34825490-2 2022 Here, a strategy is introduced to integrate P-rich NiP2 and P-poor Ni5 P4 into in-plane heterostructures by anion substitution, in which P atoms at the in-plane interfaces perform as active sites to adsorb H* and thus facilitate the hydrogen evolution reaction (HER) process via modulating the electronic structure between NiP2 and Ni5 P4 . CHEMBL2180955 67-70 BCL2 interacting protein 2 Homo sapiens 51-55 34825490-2 2022 Here, a strategy is introduced to integrate P-rich NiP2 and P-poor Ni5 P4 into in-plane heterostructures by anion substitution, in which P atoms at the in-plane interfaces perform as active sites to adsorb H* and thus facilitate the hydrogen evolution reaction (HER) process via modulating the electronic structure between NiP2 and Ni5 P4 . CHEMBL2180955 67-70 BCL2 interacting protein 2 Homo sapiens 323-327 34825490-2 2022 Here, a strategy is introduced to integrate P-rich NiP2 and P-poor Ni5 P4 into in-plane heterostructures by anion substitution, in which P atoms at the in-plane interfaces perform as active sites to adsorb H* and thus facilitate the hydrogen evolution reaction (HER) process via modulating the electronic structure between NiP2 and Ni5 P4 . Hydrogen 233-241 BCL2 interacting protein 2 Homo sapiens 51-55 34825490-2 2022 Here, a strategy is introduced to integrate P-rich NiP2 and P-poor Ni5 P4 into in-plane heterostructures by anion substitution, in which P atoms at the in-plane interfaces perform as active sites to adsorb H* and thus facilitate the hydrogen evolution reaction (HER) process via modulating the electronic structure between NiP2 and Ni5 P4 . Hydrogen 233-241 BCL2 interacting protein 2 Homo sapiens 323-327 34825490-3 2022 Consequently, the NiP2 /Ni5 P4 hybrid exhibits an outstanding hydrogen-evolving activity, requiring only 30 and 76 mV to afford 10 and 100 mA cm-2 in acid, respectively. Hydrogen 62-70 BCL2 interacting protein 2 Homo sapiens 18-22 34901657-4 2021 Studies have found that although the dosage of NiP2 is very low, its appearance has been efficient to improve the hydrogen evolution reaction (HER) performance of CoMoP, which may be induced by the synergistic effect of the two different components NiP2 and CoMoP. Hydrogen 114-122 BCL2 interacting protein 2 Homo sapiens 47-51 34901657-4 2021 Studies have found that although the dosage of NiP2 is very low, its appearance has been efficient to improve the hydrogen evolution reaction (HER) performance of CoMoP, which may be induced by the synergistic effect of the two different components NiP2 and CoMoP. Hydrogen 114-122 BCL2 interacting protein 2 Homo sapiens 249-253 34754002-2 2021 The prepared P-NiFe@CF catalyst consisted of Ni5P4, NiP2, and FeP with 3D flower-like P-NiFe architecture on CF. p-nife 13-19 BCL2 interacting protein 2 Homo sapiens 52-56 35591379-6 2022 Furthermore, because of good balance between CH4 dissociation and CO2 dissociation, NiP-2/Al2O3 catalyst exhibits best resistance of carbon deposition, few carbon depositions were formed after 50 h of dry methane reforming. Methane 45-48 BCL2 interacting protein 2 Homo sapiens 84-89 34618117-0 2021 Surviving hypoxia: aquaporin-like protein NIP2;1 mediates lactic acid transport. Lactic Acid 58-69 BCL2 interacting protein 2 Homo sapiens 42-46 34115435-0 2021 Flower-like Spherical alpha-Ni(OH)2 Derived NiP2 as Superior Anode Material of Sodium Ion Batteries. alpha-ni(oh)2 22-35 BCL2 interacting protein 2 Homo sapiens 44-48 34115435-0 2021 Flower-like Spherical alpha-Ni(OH)2 Derived NiP2 as Superior Anode Material of Sodium Ion Batteries. Sodium 79-85 BCL2 interacting protein 2 Homo sapiens 44-48 34115435-3 2021 In this paper, the NiP 2 nanoparticles encapsulated in three-dimensional graphene (NiP 2 @rGO) were obtained from the flower-like sphericalalpha-Ni(OH) 2 by phosphating and carbon encapsulation processes. Graphite 73-81 BCL2 interacting protein 2 Homo sapiens 19-24 34115435-3 2021 In this paper, the NiP 2 nanoparticles encapsulated in three-dimensional graphene (NiP 2 @rGO) were obtained from the flower-like sphericalalpha-Ni(OH) 2 by phosphating and carbon encapsulation processes. Graphite 73-81 BCL2 interacting protein 2 Homo sapiens 83-88 34115435-3 2021 In this paper, the NiP 2 nanoparticles encapsulated in three-dimensional graphene (NiP 2 @rGO) were obtained from the flower-like sphericalalpha-Ni(OH) 2 by phosphating and carbon encapsulation processes. Carbon 173-179 BCL2 interacting protein 2 Homo sapiens 19-24 34115435-3 2021 In this paper, the NiP 2 nanoparticles encapsulated in three-dimensional graphene (NiP 2 @rGO) were obtained from the flower-like sphericalalpha-Ni(OH) 2 by phosphating and carbon encapsulation processes. Carbon 173-179 BCL2 interacting protein 2 Homo sapiens 83-88 34115435-4 2021 When used as a sodium-ion batteries anode material, NiP 2 @rGO composite shows excellent cycling performance (117 mA h g -1 at 10 A g -1 after 8000 cycles). Sodium 15-21 BCL2 interacting protein 2 Homo sapiens 52-57 34115435-7 2021 The effective combination of NiP 2 nanoparticles with graphene greatly reduces the NiP 2 nanoparticles aggregation and pulverization during the discharge/charge process. Graphite 54-62 BCL2 interacting protein 2 Homo sapiens 29-34 34115435-7 2021 The effective combination of NiP 2 nanoparticles with graphene greatly reduces the NiP 2 nanoparticles aggregation and pulverization during the discharge/charge process. Graphite 54-62 BCL2 interacting protein 2 Homo sapiens 83-88 35469395-0 2022 Superhydrophilic/Superaerophobic Hierarchical NiP2@MoO2/Co(Ni)MoO4 Core-Shell Array Electrocatalysts for Efficient Hydrogen Production at Large Current Densities. molybdenum dioxide 51-55 BCL2 interacting protein 2 Homo sapiens 46-50 35469395-0 2022 Superhydrophilic/Superaerophobic Hierarchical NiP2@MoO2/Co(Ni)MoO4 Core-Shell Array Electrocatalysts for Efficient Hydrogen Production at Large Current Densities. Hydrogen 115-123 BCL2 interacting protein 2 Homo sapiens 46-50 35469395-2 2022 Herein, a hierarchical core-shell NiP2@MoO2/Co(Ni)MoO4 cuboid array electrode with superhydrophilic/superaerophobic properties is successfully fabricated and the formation mechanism of the core-shell structure is systematically investigated. molybdenum dioxide 39-43 BCL2 interacting protein 2 Homo sapiens 34-38 35469395-2 2022 Herein, a hierarchical core-shell NiP2@MoO2/Co(Ni)MoO4 cuboid array electrode with superhydrophilic/superaerophobic properties is successfully fabricated and the formation mechanism of the core-shell structure is systematically investigated. co(ni)moo4 44-54 BCL2 interacting protein 2 Homo sapiens 34-38 35469395-3 2022 Through an in situ partially converted gas-solid reaction during the phosphating process, Ni and Co elements are leached and rearranged to form NiP2 particles and amorphous CoO as the shell layer and the inner undecomposed Co(Ni)MoO4 crystals serve as the core layer. Cobalt 97-99 BCL2 interacting protein 2 Homo sapiens 144-148 35469395-4 2022 Because of its seamless core-shell structure and superhydrophilicity/superaerophobicity of hierarchical cuboid arrays, NiP2@MoO2/Co(Ni)MoO4 exhibits superior HER activity in 1 M KOH with only an overpotential of 297 mV to deliver 1000 mA cm-2 and can work steadily for 650 h at 200 mA cm-2. molybdenum dioxide 124-128 BCL2 interacting protein 2 Homo sapiens 119-123 35469395-4 2022 Because of its seamless core-shell structure and superhydrophilicity/superaerophobicity of hierarchical cuboid arrays, NiP2@MoO2/Co(Ni)MoO4 exhibits superior HER activity in 1 M KOH with only an overpotential of 297 mV to deliver 1000 mA cm-2 and can work steadily for 650 h at 200 mA cm-2. moo4 135-139 BCL2 interacting protein 2 Homo sapiens 119-123 35469395-4 2022 Because of its seamless core-shell structure and superhydrophilicity/superaerophobicity of hierarchical cuboid arrays, NiP2@MoO2/Co(Ni)MoO4 exhibits superior HER activity in 1 M KOH with only an overpotential of 297 mV to deliver 1000 mA cm-2 and can work steadily for 650 h at 200 mA cm-2. potassium hydroxide 178-181 BCL2 interacting protein 2 Homo sapiens 119-123 35591379-6 2022 Furthermore, because of good balance between CH4 dissociation and CO2 dissociation, NiP-2/Al2O3 catalyst exhibits best resistance of carbon deposition, few carbon depositions were formed after 50 h of dry methane reforming. Carbon Dioxide 66-69 BCL2 interacting protein 2 Homo sapiens 84-89 35591379-6 2022 Furthermore, because of good balance between CH4 dissociation and CO2 dissociation, NiP-2/Al2O3 catalyst exhibits best resistance of carbon deposition, few carbon depositions were formed after 50 h of dry methane reforming. Aluminum Oxide 90-95 BCL2 interacting protein 2 Homo sapiens 84-89 35591379-6 2022 Furthermore, because of good balance between CH4 dissociation and CO2 dissociation, NiP-2/Al2O3 catalyst exhibits best resistance of carbon deposition, few carbon depositions were formed after 50 h of dry methane reforming. Carbon 133-139 BCL2 interacting protein 2 Homo sapiens 84-89 35048936-0 2022 The controlled synthesis of nitrogen and iron co-doped Ni3S2@NiP2 heterostructures for the oxygen evolution reaction and urea oxidation reaction. Nitrogen 28-36 BCL2 interacting protein 2 Homo sapiens 61-65 35048936-0 2022 The controlled synthesis of nitrogen and iron co-doped Ni3S2@NiP2 heterostructures for the oxygen evolution reaction and urea oxidation reaction. Iron 41-45 BCL2 interacting protein 2 Homo sapiens 61-65 35048936-0 2022 The controlled synthesis of nitrogen and iron co-doped Ni3S2@NiP2 heterostructures for the oxygen evolution reaction and urea oxidation reaction. ni3s2 55-60 BCL2 interacting protein 2 Homo sapiens 61-65 35048936-0 2022 The controlled synthesis of nitrogen and iron co-doped Ni3S2@NiP2 heterostructures for the oxygen evolution reaction and urea oxidation reaction. Oxygen 91-97 BCL2 interacting protein 2 Homo sapiens 61-65 35048936-0 2022 The controlled synthesis of nitrogen and iron co-doped Ni3S2@NiP2 heterostructures for the oxygen evolution reaction and urea oxidation reaction. Urea 121-125 BCL2 interacting protein 2 Homo sapiens 61-65 35048936-2 2022 Herein, nitrogen and iron co-doped Ni3S2 and NiP2 heterostructures with high efficiency oxygen evolution reaction (OER) and urea oxidation reaction (UOR) performances were firstly successfully prepared on nickel foam by hydrothermal and high-temperature calcination methods. Nitrogen 8-16 BCL2 interacting protein 2 Homo sapiens 45-49 35048936-2 2022 Herein, nitrogen and iron co-doped Ni3S2 and NiP2 heterostructures with high efficiency oxygen evolution reaction (OER) and urea oxidation reaction (UOR) performances were firstly successfully prepared on nickel foam by hydrothermal and high-temperature calcination methods. Iron 21-25 BCL2 interacting protein 2 Homo sapiens 45-49 35048936-2 2022 Herein, nitrogen and iron co-doped Ni3S2 and NiP2 heterostructures with high efficiency oxygen evolution reaction (OER) and urea oxidation reaction (UOR) performances were firstly successfully prepared on nickel foam by hydrothermal and high-temperature calcination methods. Oxygen 88-94 BCL2 interacting protein 2 Homo sapiens 45-49 35048936-2 2022 Herein, nitrogen and iron co-doped Ni3S2 and NiP2 heterostructures with high efficiency oxygen evolution reaction (OER) and urea oxidation reaction (UOR) performances were firstly successfully prepared on nickel foam by hydrothermal and high-temperature calcination methods. Urea 124-128 BCL2 interacting protein 2 Homo sapiens 45-49 35048936-2 2022 Herein, nitrogen and iron co-doped Ni3S2 and NiP2 heterostructures with high efficiency oxygen evolution reaction (OER) and urea oxidation reaction (UOR) performances were firstly successfully prepared on nickel foam by hydrothermal and high-temperature calcination methods. Nickel 205-211 BCL2 interacting protein 2 Homo sapiens 45-49 35048936-3 2022 Benefiting from the hierarchical structure, the exposure of more active sites and the doping effect of N and Fe, the N-Fe-Ni3S2@NiP2/NF material showed excellent electrocatalytic activity for the OER and UOR. Nitrogen 103-104 BCL2 interacting protein 2 Homo sapiens 128-132 35048936-3 2022 Benefiting from the hierarchical structure, the exposure of more active sites and the doping effect of N and Fe, the N-Fe-Ni3S2@NiP2/NF material showed excellent electrocatalytic activity for the OER and UOR. Iron 109-111 BCL2 interacting protein 2 Homo sapiens 128-132 35048936-3 2022 Benefiting from the hierarchical structure, the exposure of more active sites and the doping effect of N and Fe, the N-Fe-Ni3S2@NiP2/NF material showed excellent electrocatalytic activity for the OER and UOR. n-fe-ni3s2 117-127 BCL2 interacting protein 2 Homo sapiens 128-132 35048936-4 2022 The N-Fe-Ni3S2@NiP2/NF material displays excellent catalytic OER performance; the overpotential is only 251 mV to drive 100 mA cm-2 current density, while for the UOR, the potential is only 1.353 V to drive 100 mA cm-2 current density, which is one of the best catalytic activities reported so far. n-fe-ni3s2 4-14 BCL2 interacting protein 2 Homo sapiens 15-19 35048936-5 2022 It is worth noting that scanning electron microscopy showed that the surface of N-Fe-Ni3S2@NiP2/NF is rough and has some mesopores, which may have resulted in an increase of active sites during the electrocatalytic process. n-fe-ni3s2 80-90 BCL2 interacting protein 2 Homo sapiens 91-95 35048936-6 2022 The N-Fe-Ni3S2@NiP2/NF electrode couple also has relatively long-term durability in alkaline solutions, maintaining a stable current density for 15 h at 1.35 V. The density functional theory (DFT) calculation shows that the in situ generated Fe doped nanooxides exhibit strong water adsorption energy, which may be one of the reasons for the good catalytic activity. n-fe-ni3s2 4-14 BCL2 interacting protein 2 Homo sapiens 15-19 35048936-6 2022 The N-Fe-Ni3S2@NiP2/NF electrode couple also has relatively long-term durability in alkaline solutions, maintaining a stable current density for 15 h at 1.35 V. The density functional theory (DFT) calculation shows that the in situ generated Fe doped nanooxides exhibit strong water adsorption energy, which may be one of the reasons for the good catalytic activity. fe doped nanooxides 242-261 BCL2 interacting protein 2 Homo sapiens 15-19 35048936-6 2022 The N-Fe-Ni3S2@NiP2/NF electrode couple also has relatively long-term durability in alkaline solutions, maintaining a stable current density for 15 h at 1.35 V. The density functional theory (DFT) calculation shows that the in situ generated Fe doped nanooxides exhibit strong water adsorption energy, which may be one of the reasons for the good catalytic activity. Water 277-282 BCL2 interacting protein 2 Homo sapiens 15-19