PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
31663563-0	2019	3D architectures with Co2(OH)2CO3 nanowires wrapped by reduced graphene oxide as superior rate anode materials for Li-ion batteries.	Graphite	63-77	complement C2	Homo sapiens	22-25	
31790227-2	2019	Herein, based on a series of metal-free single-layer graphene nanodisks (GNDs) with different surface contents of oxygen-containing groups for highly efficient electrocatalytic reduction reaction of CO2 (CO2RR) to produce formate (HCOO-), we find that the CO2RR catalytic performance is only positively correlated with the surface content of carboxyl groups.	Graphite	53-61	complement C2	Homo sapiens	204-209	
31790227-2	2019	Herein, based on a series of metal-free single-layer graphene nanodisks (GNDs) with different surface contents of oxygen-containing groups for highly efficient electrocatalytic reduction reaction of CO2 (CO2RR) to produce formate (HCOO-), we find that the CO2RR catalytic performance is only positively correlated with the surface content of carboxyl groups.	Graphite	53-61	complement C2	Homo sapiens	256-261	
31752488-4	2019	On the other hand, dispersion of Co2-MOF in an alcoholic solution of Nafion gives rise to a composite (Co2-MOF@Nafion) with a high resistance to hydrolysis in aqueous media and good adherence to graphite electrodes.	Graphite	195-203	complement C2	Homo sapiens	33-36	
31752488-4	2019	On the other hand, dispersion of Co2-MOF in an alcoholic solution of Nafion gives rise to a composite (Co2-MOF@Nafion) with a high resistance to hydrolysis in aqueous media and good adherence to graphite electrodes.	Graphite	195-203	complement C2	Homo sapiens	103-106	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	24-38	complement C2	Homo sapiens	3-6	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	24-38	complement C2	Homo sapiens	53-56	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	66-68	complement C2	Homo sapiens	3-6	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	342-344	complement C2	Homo sapiens	3-6	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	342-344	complement C2	Homo sapiens	53-56	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	342-344	complement C2	Homo sapiens	3-6	
31680476-3	2019	2D Co2/3Ni1/3 hydroxide/graphene oxide superlattice (Co2/3Ni1/3NS-GO) was characterized with a high activity of achieving an current density of 10 mA cm-2 at a low overpotential of 259 mV accompanied by a small Tafel slope of 35.7 mV dec-1, surpassing nanocones and 2D nanosheets as well as the congeneric heterostructured Co1-xNix hydroxide-GO nanoarchitectures (Co1-xNixNS-GO, x=0, 1/2, 1/4, 1) and commercial RuO2 electroctalyst.	Graphite	342-344	complement C2	Homo sapiens	53-56	
31680476-4	2019	The outstanding activity of Co2/3Ni1/3NS-GO superlattice uncovers the combined merits of 2D superlattice-like structure and composition optimization for electrocatalysis, providing a strategy for developing high-performance electrochemical materials by rational morphology and composition design.	Graphite	41-43	complement C2	Homo sapiens	28-31	
31252480-4	2019	Herein, we report the use of a defect-free graphene positive electrode, which was produced using the electrochemical exfoliation of graphite in an aqueous solution with the aid of Co2+ as an antioxidant.	Graphite	43-51	complement C2	Homo sapiens	180-183	
31573003-0	2019	Synergistic effect of supercritical CO2 and organic solvent on exfoliation of graphene: experiment and atomistic simulation studies.	Graphite	78-86	complement C2	Homo sapiens	36-39	
31573003-1	2019	In this work, experiments and molecular dynamics (MD) simulations are carried out to explore the synergistic effect of supercritical CO2 (scCO2) and organic solvent on intercalation and exfoliation of graphene.	Graphite	201-209	complement C2	Homo sapiens	133-136	
31364838-2	2019	The accepted underlying mechanism is the deposition of Co2+ on the graphite anode that destroys the interphase.	Graphite	67-75	complement C2	Homo sapiens	55-58	
31364838-3	2019	In this work, we report that the dissolved Co2+ exists in the form of both Co0 and Co2+ on the graphite anode surface, while Co0 formed at lithium insertion potential can be reoxidized to Co2+ during charging.	Graphite	95-103	complement C2	Homo sapiens	43-46	
31364838-3	2019	In this work, we report that the dissolved Co2+ exists in the form of both Co0 and Co2+ on the graphite anode surface, while Co0 formed at lithium insertion potential can be reoxidized to Co2+ during charging.	Graphite	95-103	complement C2	Homo sapiens	83-86	
31364838-3	2019	In this work, we report that the dissolved Co2+ exists in the form of both Co0 and Co2+ on the graphite anode surface, while Co0 formed at lithium insertion potential can be reoxidized to Co2+ during charging.	Graphite	95-103	complement C2	Homo sapiens	83-86	
31364838-6	2019	The understanding of the destructive role of the dissolved Co2+ on the interphasial stability of the graphite electrode and an effective strategy to suppress such a failure mechanism provides fresh insight into the failure mechanism of manganese-based cathode chemistries, which serves as a better guideline for electrolyte design for future batteries.	Graphite	101-109	complement C2	Homo sapiens	59-62	
30695754-4	2019	No charge transfer from the substrate to the organic layer is observed in the germanium intercalated case, while interface related peaks in the Co 2p core level spectra indicate such charge transfer on graphene/nickel.	Graphite	202-210	complement C2	Homo sapiens	144-149	
27790664-1	2016	Co2+ ions encapsulated in nitrogen doped graphene were applied as an oxygen evolution catalyst.	Graphite	41-49	complement C2	Homo sapiens	0-3	
30511767-7	2019	Thus, photo-generated electrons from hybrid states of In2 O3 , composed of In 5s and 2p orbitals, are transferred into the hybrid states of N-doped graphite, composed of C 2p and N 2p orbitals.	Graphite	148-156	complement C2	Homo sapiens	170-174	
28520429-3	2017	We demonstrate that the low-energy signals on Raman spectra of plasma-seeded grown graphene sheets originated from nanocurvature (c) of mono- (175 and 325-500 cm-1 signals) (c   1 nm) and bilayer (118 cm-1 peak) (c   2 nm) graphene with Raman simulations, based on Raman radial mode (RM) Eigen vectors.	Graphite	83-91	complement C2	Homo sapiens	213-218	
26395160-7	2015	The improved responsivity is attributed to optical transitions between O 2p orbitals in the valence band of TiO2 and C 2p orbitals in the conduction band of graphene enabled by Coulomb interactions at the interface.	Graphite	157-165	complement C2	Homo sapiens	117-121	
34405998-3	2021	We find that graphene introduces C 2p states at the Fermi level, rendering the composite semimetallic, and thus the electrical properties are predicted to be highly sensitive to the amount and quality of the graphene.	Graphite	13-21	complement C2	Homo sapiens	33-37	
34405998-3	2021	We find that graphene introduces C 2p states at the Fermi level, rendering the composite semimetallic, and thus the electrical properties are predicted to be highly sensitive to the amount and quality of the graphene.	Graphite	208-216	complement C2	Homo sapiens	33-37