Keyword search (4,163 papers available)

"Singh P" Authored Publications:

Title Authors PubMed ID
1 Luminescent Electro-Spun Nanofibers Crosslinked with Boronic Esters Exhibiting Controlled Release of Carbon Dots for Detection of Wound pHs and Enhanced Antimicrobial Lokuge ND; Casillas-Popova SN; Singh P; Clermont-Paquette A; Skinner CD; Findlay BL; Naccache R; Oh JK; 40920389
BIOLOGY
2 Multi-stimuli-responsive degradable boronic ester-crosslinked e-spun nanofiber wound dressings Casillas-Popova SN; Lokuge ND; Singh P; Cirillo A; Thinphang-Nga A; Skinner CD; Vuckovic D; Findlay BL; Oh JK; 40557709
BIOLOGY
3 Defective GaAs nanoribbon-based biosensor for lung cancer biomarkers: a DFT study Tarun T; Singh P; Kaur H; Walia GK; Randhawa DKK; Choudhary BC; 34459994
ENCS
4 Finite Element Modelling of Bandgap Engineered Graphene FET with the Application in Sensing Methanethiol Biomarker. Singh P, Abedini Sohi P, Kahrizi M 33467459
ENCS
5 Analysis of uric acid adsorption on armchair silicene nanoribbons: a DFT study. Tarun T, Randhawa DKK, Singh P, Choudhary BC, Walia GK, Kaur N 32108912
ENCS
6 First principles investigation on armchair zinc oxide nanoribbons as uric acid sensors. Singh P, Randhawa DKK, Tarun, Choudhary BC, Walia GK, Kaur N 31834483
ENCS

 

Title:Finite Element Modelling of Bandgap Engineered Graphene FET with the Application in Sensing Methanethiol Biomarker.
Authors:Singh PAbedini Sohi PKahrizi M
Link:https://www.ncbi.nlm.nih.gov/pubmed/33467459
DOI:10.3390/s21020580
Publication:Sensors (Basel, Switzerland)
Keywords:COMSOL modellingDFTGFETbandgap engineeringfunctionalized graphenemethanethiol biosensor
PMID:33467459 Category:Sensors (Basel) Date Added:2021-01-21
Dept Affiliation: ENCS
1 Department of Electrical and Computer Engineering, Concordia University, Montreal, QC H3G1M8, Canada.

Description:

Finite Element Modelling of Bandgap Engineered Graphene FET with the Application in Sensing Methanethiol Biomarker.

Sensors (Basel). 2021 Jan 15; 21(2):

Authors: Singh P, Abedini Sohi P, Kahrizi M

Abstract

In this work, we have designed and simulated a graphene field effect transistor (GFET) with the purpose of developing a sensitive biosensor for methanethiol, a biomarker for bacterial infections. The surface of a graphene layer is functionalized by manipulation of its surface structure and is used as the channel of the GFET. Two methods, doping the crystal structure of graphene and decorating the surface by transition metals (TMs), are utilized to change the electrical properties of the graphene layers to make them suitable as a channel of the GFET. The techniques also change the surface chemistry of the graphene, enhancing its adsorption characteristics and making binding between graphene and biomarker possible. All the physical parameters are calculated for various variants of graphene in the absence and presence of the biomarker using counterpoise energy-corrected density functional theory (DFT). The device was modelled using COMSOL Multiphysics. Our studies show that the sensitivity of the device is affected by structural parameters of the device, the electrical properties of the graphene, and with adsorption of the biomarker. It was found that the devices made of graphene layers decorated with TM show higher sensitivities toward detecting the biomarker compared with those made by doped graphene layers.

PMID: 33467459 [PubMed - in process]




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