PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
35630991-5	2022	Numerical results show that the optical force is generated due to the localized surface plasmonic resonance (LSPR) mode of the graphene discs with Fermi Energy Ef = 0.6 eV under incident intensity I = 1 mW/mum2, which has a very low incident intensity compared to other plasmonic tweezers systems.	Graphite	127-135	trafficking protein particle complex subunit 1	Homo sapiens	206-210	
35587781-3	2022	The impedance of the graphene/Ag electrode is reduced to 161.4 +- 13.4 MOmega mum2, while the cathode charge-storage capacity (CSCc) reaches 24.2 +- 1.9 mC cm-2, which is 6.3 and 48.4 times higher than those of the commercial Ag electrodes, respectively.	Graphite	21-29	trafficking protein particle complex subunit 1	Homo sapiens	78-82	
34673562-5	2021	The material prepared under optimized conditions included edge-defect-free graphene nanosheets (~ 0.0034 mum2) and hBN (~ 0.0038 mum2) per unit area of 1 mum2.	Graphite	75-83	trafficking protein particle complex subunit 1	Homo sapiens	105-109	
35435683-2	2022	Herein, we present IR spectroscopy and imaging based on multilayer-graphene microemitters, which have distinct features: a planar structure, bright intensity, a small footprint (sub-mum2), and high modulation speed of >50 kHz.	Graphite	67-75	trafficking protein particle complex subunit 1	Homo sapiens	182-186	
32541673-4	2020	First is the consistency of its exfoliation process in increasing the yield and in producing large (>10,000 mum2) monolayer graphene.	Graphite	124-132	trafficking protein particle complex subunit 1	Homo sapiens	108-112	
32867054-3	2020	According to the Raman spectra and large-area (16 x 16 mum2) Raman mapping, a low-defect, >95% coverage bilayer and high-uniformity graphene were successfully obtained by camphor-based CVD processes.	Graphite	132-140	trafficking protein particle complex subunit 1	Homo sapiens	55-59	
30850594-4	2019	The detected signal corresponds to a gas molecule layer adsorbed on the graphene surface with a concentration of 800 zeptomole per mum2, which is made possible by the strong field confinement of graphene plasmons and high physisorption of gas molecules on the graphene nanoribbons.	Graphite	72-80	trafficking protein particle complex subunit 1	Homo sapiens	131-135	
30793731-4	2019	In a graphene membrane with high built-in tension, but still of macroscopic size with dimensions 3 x 1 mum2, a record resonance frequency of 1.17 GHz is observed after the final current annealing step.	Graphite	5-13	trafficking protein particle complex subunit 1	Homo sapiens	103-107	
31016416-3	2019	From Raman mapping analysis, shorter distance of 1 cm and temperature of around 950  C lead to the growth of large-area single-layer graphene with a coverage up to 97% of the measured area size of 6400 mum2.	Graphite	133-141	trafficking protein particle complex subunit 1	Homo sapiens	202-206	
30850594-4	2019	The detected signal corresponds to a gas molecule layer adsorbed on the graphene surface with a concentration of 800 zeptomole per mum2, which is made possible by the strong field confinement of graphene plasmons and high physisorption of gas molecules on the graphene nanoribbons.	Graphite	195-203	trafficking protein particle complex subunit 1	Homo sapiens	131-135	
30850594-4	2019	The detected signal corresponds to a gas molecule layer adsorbed on the graphene surface with a concentration of 800 zeptomole per mum2, which is made possible by the strong field confinement of graphene plasmons and high physisorption of gas molecules on the graphene nanoribbons.	Graphite	195-203	trafficking protein particle complex subunit 1	Homo sapiens	131-135	
30568160-5	2018	We fabricate blister-free regions of graphene encapsulated in hexagonal boron nitride with an area ~ 5000 mum2, achieving mobilities up to 180,000 cm2 V-1 s-1 at room temperature, and 1.8 x 106 cm2 V-1 s-1 at 9 K. We also assemble heterostructures using graphene intentionally exposed to polymers and solvents.	Graphite	37-45	trafficking protein particle complex subunit 1	Homo sapiens	106-110