PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
34510595-0	2021	Direct Chemical Vapor Deposition Synthesis of Porous Single-Layer Graphene Membranes with High Gas Permeances and Selectivities.	Graphite	66-74	gastrin	Homo sapiens	95-98	
34927434-4	2021	Here, we propose a method for actively implementing the photoinduced modulation of SERS signals, which is that under UV irradiation, the Fermi level of graphene can be dynamically modulated due to the adsorption and desorption of gas molecules.	Graphite	152-160	gastrin	Homo sapiens	230-233	
34517613-0	2021	Strategies for the performance enhancement of graphene-based gas sensors: A review.	Graphite	46-54	gastrin	Homo sapiens	61-64	
34517613-2	2021	Graphene, with unique structure and characteristic properties, has been considered as a promising candidate for fabricating high-performance gas sensor.	Graphite	0-8	gastrin	Homo sapiens	141-144	
34517613-3	2021	Great efforts in current research are directed towards exploiting various graphene-based gas sensors, but the core of gas sensing study is how to enhance the gas sensing performance.	Graphite	74-82	gastrin	Homo sapiens	89-92	
34517613-3	2021	Great efforts in current research are directed towards exploiting various graphene-based gas sensors, but the core of gas sensing study is how to enhance the gas sensing performance.	Graphite	74-82	gastrin	Homo sapiens	118-121	
34517613-3	2021	Great efforts in current research are directed towards exploiting various graphene-based gas sensors, but the core of gas sensing study is how to enhance the gas sensing performance.	Graphite	74-82	gastrin	Homo sapiens	158-161	
34517613-4	2021	Herein, we propose a perspective that focuses on the strategies for sensing performance enhancement of graphene-based gas sensors.	Graphite	103-111	gastrin	Homo sapiens	118-121	
34914376-0	2021	Interfacial Ammonia Selectivity, Atmospheric Passivation, and Molecular Identification in Graphene-Nanopored Activated Carbon Molecular-Sieve Gas Sensors.	Graphite	90-98	gastrin	Homo sapiens	142-145	
34914376-3	2021	Herein, target gas sensing at the graphene-activated carbon interface of a graphene-nanopored activated carbon molecular-sieve sensor obtained via the postlithographic pyrolysis of Novolac resin residues on graphene nanoribbons is shown to simultaneously induce ammonia selectivity and atmospheric passivation of graphene.	Graphite	34-42	gastrin	Homo sapiens	15-18	
34914376-3	2021	Herein, target gas sensing at the graphene-activated carbon interface of a graphene-nanopored activated carbon molecular-sieve sensor obtained via the postlithographic pyrolysis of Novolac resin residues on graphene nanoribbons is shown to simultaneously induce ammonia selectivity and atmospheric passivation of graphene.	Graphite	75-83	gastrin	Homo sapiens	15-18	
34914376-3	2021	Herein, target gas sensing at the graphene-activated carbon interface of a graphene-nanopored activated carbon molecular-sieve sensor obtained via the postlithographic pyrolysis of Novolac resin residues on graphene nanoribbons is shown to simultaneously induce ammonia selectivity and atmospheric passivation of graphene.	Graphite	207-215	gastrin	Homo sapiens	15-18	
34914376-3	2021	Herein, target gas sensing at the graphene-activated carbon interface of a graphene-nanopored activated carbon molecular-sieve sensor obtained via the postlithographic pyrolysis of Novolac resin residues on graphene nanoribbons is shown to simultaneously induce ammonia selectivity and atmospheric passivation of graphene.	Graphite	313-321	gastrin	Homo sapiens	15-18	
34914376-4	2021	Consequently, 500 parts per trillion (ppt) ammonia sensitivity in atmospheric air is achieved with a response time of ~3 s. The similar graphene and a-C workfunctions ensure that the ambipolar and gas-adsorption-induced charge transfer characteristics of pristine graphene are retained.	Graphite	264-272	gastrin	Homo sapiens	197-200	
34510595-1	2021	Single-layer graphene containing molecular-sized in-plane pores is regarded as a promising membrane material for high-performance gas separations due to its atomic thickness and low gas transport resistance.	Graphite	13-21	gastrin	Homo sapiens	130-133	
34510595-1	2021	Single-layer graphene containing molecular-sized in-plane pores is regarded as a promising membrane material for high-performance gas separations due to its atomic thickness and low gas transport resistance.	Graphite	13-21	gastrin	Homo sapiens	182-185	
34510595-4	2021	Therefore, intrinsically porous graphene can exhibit high pore density while maintaining its gas selectivity.	Graphite	32-40	gastrin	Homo sapiens	93-96	
34510595-7	2021	Moreover, it is identified that nanoscale molecular fouling of the graphene surface during gas separation where graphene pores are partially blocked by hydrocarbon contaminants under experimental conditions, controls both selectivity and temperature dependent permeance.	Graphite	67-75	gastrin	Homo sapiens	91-94	
34510595-7	2021	Moreover, it is identified that nanoscale molecular fouling of the graphene surface during gas separation where graphene pores are partially blocked by hydrocarbon contaminants under experimental conditions, controls both selectivity and temperature dependent permeance.	Graphite	112-120	gastrin	Homo sapiens	91-94	
34510595-8	2021	Overall, the direct synthesis of porous single-layer graphene exploits its tremendous potential as high-performance gas-sieving membranes.	Graphite	53-61	gastrin	Homo sapiens	116-119	
35129991-0	2022	How Gas-Solid Interaction Matters in Graphene-Doped Silica Aerogels.	Graphite	37-45	gastrin	Homo sapiens	4-7	
34164032-0	2021	Investigating states of gas in water encapsulated between graphene layers.	Graphite	58-66	gastrin	Homo sapiens	24-27	
35156288-2	2022	Graphene is considered a promising material for gas sensing applications, its functionalization often being a requisite.	Graphite	0-8	gastrin	Homo sapiens	48-51	
34164032-3	2021	To close this gap, here we used transmission electron microscopy (TEM) to study degassed water, deionized water, and gas-supersaturated water encapsulated in graphene liquid cells.	Graphite	158-166	gastrin	Homo sapiens	117-120	
35389537-1	2022	Porous graphene and other atomically thin two-dimensional materials are regarded as highly promising membrane materials for high-performance gas separations due to their atomic thickness, large-scale synthesizability, excellent mechanical strength, and chemical stability.	Graphite	7-15	gastrin	Homo sapiens	141-144	
35129991-6	2022	Inspired by the visualization of the 3D pore structure, we proposed a graphene/silica/nitrogen model to evaluate the role of graphene in heat conduction: it can not only reduce effective gas collision (impede heat transport) but also enhance the gas-solid coupling effect.	Graphite	70-78	gastrin	Homo sapiens	187-190	
35129991-6	2022	Inspired by the visualization of the 3D pore structure, we proposed a graphene/silica/nitrogen model to evaluate the role of graphene in heat conduction: it can not only reduce effective gas collision (impede heat transport) but also enhance the gas-solid coupling effect.	Graphite	70-78	gastrin	Homo sapiens	246-249	
35129991-6	2022	Inspired by the visualization of the 3D pore structure, we proposed a graphene/silica/nitrogen model to evaluate the role of graphene in heat conduction: it can not only reduce effective gas collision (impede heat transport) but also enhance the gas-solid coupling effect.	Graphite	125-133	gastrin	Homo sapiens	187-190	
35129991-6	2022	Inspired by the visualization of the 3D pore structure, we proposed a graphene/silica/nitrogen model to evaluate the role of graphene in heat conduction: it can not only reduce effective gas collision (impede heat transport) but also enhance the gas-solid coupling effect.	Graphite	125-133	gastrin	Homo sapiens	246-249	
33876814-6	2021	This review examines recent studies of both experiments and theoretical modeling of gas hydrates within four categories of nanoporous material hosts that include porous carbons, metal-organic frameworks, graphene nanoslits, and carbon nanotubes.	Graphite	204-212	gastrin	Homo sapiens	84-87	
35207867-0	2022	The Synergistic Properties and Gas Sensing Performance of Functionalized Graphene-Based Sensors.	Graphite	73-81	gastrin	Homo sapiens	31-34	
35054626-4	2022	Based on the calculation results, the inferred key factors affecting the gas permeability of CMS membrane were the fractional free volume (FFV) of the precursor, the average interlayer spacing of graphite-like carbon sheet, and the final carbonization temperature.	Graphite	196-204	gastrin	Homo sapiens	73-76	
35071915-0	2022	Theoretical Approach to Evaluate the Gas-Sensing Performance of Graphene Nanoribbon/Oligothiophene Composites.	Graphite	64-72	gastrin	Homo sapiens	37-40	
35071915-1	2022	Composite formation with graphene is an effective approach to increase the sensitivity of polythiophene (nPT) gas sensors.	Graphite	25-33	gastrin	Homo sapiens	110-113	
33599473-0	2021	Decimeter-Scale Atomically Thin Graphene Membranes for Gas-Liquid Separation.	Graphite	32-40	gastrin	Homo sapiens	55-58	
33599473-1	2021	Graphene holds great potential for fabricating ultrathin selective membranes possessing high permeability without compromising selectivity and has attracted intensive interest in developing high-performance separation membranes for desalination, natural gas purification, hemodialysis, distillation, and other gas-liquid separation.	Graphite	0-8	gastrin	Homo sapiens	254-257	
33599473-1	2021	Graphene holds great potential for fabricating ultrathin selective membranes possessing high permeability without compromising selectivity and has attracted intensive interest in developing high-performance separation membranes for desalination, natural gas purification, hemodialysis, distillation, and other gas-liquid separation.	Graphite	0-8	gastrin	Homo sapiens	310-313	
33672959-2	2021	On the other hand, in its pristine form, graphene has shortages and is generally utilized in combination with other metal oxides to improve gas sensing capabilities.	Graphite	41-49	gastrin	Homo sapiens	140-143	
33255958-0	2020	Graphene and Perovskite-Based Nanocomposite for Both Electrochemical and Gas Sensor Applications: An Overview.	Graphite	0-8	gastrin	Homo sapiens	73-76	
33439000-0	2021	Predicting Gas Separation through Graphene Nanopore Ensembles with Realistic Pore Size Distributions.	Graphite	34-42	gastrin	Homo sapiens	11-14	
33439000-1	2021	The development of nanoporous single-layer graphene membranes for gas separation has prompted increasing theoretical investigations of gas transport through graphene nanopores.	Graphite	43-51	gastrin	Homo sapiens	66-69	
33439000-1	2021	The development of nanoporous single-layer graphene membranes for gas separation has prompted increasing theoretical investigations of gas transport through graphene nanopores.	Graphite	43-51	gastrin	Homo sapiens	135-138	
33439000-1	2021	The development of nanoporous single-layer graphene membranes for gas separation has prompted increasing theoretical investigations of gas transport through graphene nanopores.	Graphite	157-165	gastrin	Homo sapiens	135-138	
33439000-2	2021	However, computer simulations and theories that predict gas permeances through individual graphene nanopores are not suitable to describe experimental results, because a realistic graphene membrane contains a large number of nanopores of diverse sizes and shapes.	Graphite	90-98	gastrin	Homo sapiens	56-59	
33439000-6	2021	We also quantitatively predict the increase of the gas permeances and the decrease of the selectivities between the gases as functions of the etching time of graphene.	Graphite	158-166	gastrin	Homo sapiens	51-54	
33439000-9	2021	In general, our study highlights the effects of the pore size and shape distributions of a graphene nanopore ensemble on its gas separation properties and calls into attention the potential effect of pore-clogging contamination in experiments.	Graphite	91-99	gastrin	Homo sapiens	125-128	
33348560-0	2020	Graphene-Doped Tin Oxide Nanofibers and Nanoribbons as Gas Sensors to Detect Biomarkers of Different Diseases through the Breath.	Graphite	0-8	gastrin	Homo sapiens	55-58	
33540619-0	2021	Oxygen-Deficient Stannic Oxide/Graphene for Ultrahigh-Performance Supercapacitors and Gas Sensors.	Graphite	31-39	gastrin	Homo sapiens	86-89	
33540619-1	2021	The metal oxides/graphene nanocomposites have great application prospects in the fields of electrochemical energy storage and gas sensing detection.	Graphite	17-25	gastrin	Homo sapiens	126-129	
33540619-3	2021	Here, SnO2/graphene nanocomposite is taken as a typical example and develops a universal synthesis method that overcome these challenges and prepares the oxygen-deficient SnO2 hollow nanospheres/graphene (r-SnO2/GN) nanocomposite with excellent performance for supercapacitors and gas sensors.	Graphite	11-19	gastrin	Homo sapiens	281-284	
33255958-1	2020	Perovskite and graphene-based nanocomposites have attracted much attention and been proven as promising candidates for both gas (H2S and NH3) and electrochemical (H2O2, CH3OH and glucose) sensor applications.	Graphite	15-23	gastrin	Homo sapiens	124-127	
33064492-0	2020	Broadening the Gas Separation Utility of Monolayer Nanoporous Graphene Membranes by an Ionic Liquid Gating.	Graphite	62-70	gastrin	Homo sapiens	15-18	
33118096-0	2020	Gas separation using graphene nanosheet: insights from theory and simulation.	Graphite	21-29	gastrin	Homo sapiens	0-3	
33118096-6	2020	Gas separation, including carbon dioxide capture, gas storage, natural gas sweetening, and flue gas purification through porous graphene, is of great interest.	Graphite	128-136	gastrin	Homo sapiens	0-3	
33118096-7	2020	Porous graphene with narrow pore distribution provides exciting opportunities in gas separation processes.	Graphite	7-15	gastrin	Homo sapiens	81-84	
32725109-0	2020	Magnetic Graphene Dispersive Solid-Phase Extraction for the Determination of Phthalic Acid Esters in Flavoring Essences by Gas Chromatography Tandem Mass Spectrometry.	Graphite	9-17	gastrin	Homo sapiens	123-126	
32905337-0	2020	Functionalized Graphene Surfaces for Selective Gas Sensing.	Graphite	15-23	gastrin	Homo sapiens	47-50	
32905337-2	2020	Graphene is among the most promising materials considered for next-generation gas sensing due to its properties such as mechanical strength and flexibility, high surface-to-volume ratio, large conductivity, and low electrical noise.	Graphite	0-8	gastrin	Homo sapiens	78-81	
32905337-3	2020	While gas sensors based on graphene devices have already demonstrated high sensitivity, one of the most important figures of merit, selectivity, remains a challenge.	Graphite	27-35	gastrin	Homo sapiens	6-9	
32560886-0	2020	Radiological characterisation of graphite components in Advanced Gas-cooled Reactor cores.	Graphite	33-41	gastrin	Homo sapiens	65-68	
32692922-1	2020	We present that the porous two-layer membranes of graphene and hexagonal boron nitride (h-BN) is promising for gas mixture separation.	Graphite	50-58	gastrin	Homo sapiens	111-114	
32692922-4	2020	Finally, based on the distinctive permeation rates in the two directions, a gas separation system with two back-to-back arrayed graphene/h-BN membranes with big pores is designed to realize gas separation.	Graphite	128-136	gastrin	Homo sapiens	76-79	
32692922-4	2020	Finally, based on the distinctive permeation rates in the two directions, a gas separation system with two back-to-back arrayed graphene/h-BN membranes with big pores is designed to realize gas separation.	Graphite	128-136	gastrin	Homo sapiens	190-193	
31532436-8	2019	Moreover, wearable graphene sensors to detect mechanical, electrophysiological, fluid, and gas signals will be introduced.	Graphite	19-27	gastrin	Homo sapiens	91-94	
32486402-3	2020	The graphite morphology gradually deteriorated with the increase in the nitrogen gas injection time.	Graphite	4-12	gastrin	Homo sapiens	81-84	
32466513-0	2020	Applications of Graphene and Its Derivatives in the Upstream Oil and Gas Industry: A Systematic Review.	Graphite	16-24	gastrin	Homo sapiens	69-72	
32466513-4	2020	Combined with the actual requirements for well working fluids, chemical enhanced oil recovery, heavy oil recovery, profile control and water shutoff, tracers, oily wastewater treatment, pipeline corrosion prevention treatment, and tools and apparatus, etc., this paper introduces the behavior in water and toxicity to organisms of graphene and its derivatives in detail, and comprehensively reviews the research progress of graphene materials in the upstream oil and gas industry.	Graphite	331-339	gastrin	Homo sapiens	467-470	
31833364-1	2019	UV-sensitive lateral all-two-dimensional (2D) photodetecting devices are produced by growing the large band gap layered GaS between graphene electrode pairs directly using chemical vapor deposition methods.	Graphite	132-140	gastrin	Homo sapiens	120-123	
31833364-3	2019	We show that the surface chemistry of the substrate during GaS leads to selective growth in graphene gaps, forming the lateral heterostructures, rather than on the surface of graphene.	Graphite	92-100	gastrin	Homo sapiens	59-62	
31833364-4	2019	The graphene/GaS/graphene lateral photodetecting devices are demonstrated to be sensitive to UV light only, with no measurable response to visible light.	Graphite	4-12	gastrin	Homo sapiens	13-16	
31833364-4	2019	The graphene/GaS/graphene lateral photodetecting devices are demonstrated to be sensitive to UV light only, with no measurable response to visible light.	Graphite	17-25	gastrin	Homo sapiens	13-16	
25244511-6	2014	Finally, the properties of three-dimensionally controlled graphene-based systems are highlighted for their use as batteries, strengthening additives, gas or liquid sorbents, chemical reactor platforms, and supercapacitors.	Graphite	58-66	gastrin	Homo sapiens	150-153