Keyword search (4,164 papers available)

"graphene" Keyword-tagged Publications:

Title Authors PubMed ID
1 Synthesis and Characterization of CNC/CNF/rGO Composite Films for Advanced Functional Applications Ramezani G; Stiharu I; van de Ven TGM; Ramezani H; Nerguizian V; 41900273
ENCS
2 Scalable Synthesis of High-Quality Graphene Quantum Dots by Reductive Intercalation/Exfoliation of Coal Bepete G; Ratnayake G; Sanchez DE; Yu Z; Dimitrov E; Fest Carreno A; Oliveira MCD; Viana BC; Santos FEP; Terrones M; 41081673
PHYSICS
3 Lasso Model-Based Optimization of CNC/CNF/rGO Nanocomposites Ramezani G; Silva IO; Stiharu I; Ven TGMV; Nerguizian V; 40283268
ENCS
4 Mechanical Control of Quantum Transport in Graphene McRae AC; Wei G; Huang L; Yigen S; Tayari V; Champagne AR; 38558481
PHYSICS
5 Sodium alginate/polyvinyl alcohol semi-interpenetrating hydrogels reinforced with PEG-grafted-graphene oxide Mehrjou A; Hadaeghnia M; Ehsani Namin P; Ghasemi I; 38423903
ENCS
6 Transverse Magnetic Surface Plasmons in Graphene Nanoribbon Qubits: The Influence of a VO2 Substrate Bahrami M; Vasilopoulos P; 36839087
PHYSICS
7 A spin modulating device, tuned by the Fermi energy, in honeycomb-like substrates periodically stubbed with transition-metal-dichalkogenides Belayadi A; Vasilopoulos P; 36301679
PHYSICS
8 RPA Plasmons in Graphene Nanoribbons: Influence of a VO2 Substrate Bahrami M; Vasilopoulos P; 36014730
PHYSICS
9 Inhomogeneous linear responses and transport in armchair graphene nanoribbons in the presence of elastic scattering Bahrami M; Vasilopoulos P; 35090140
PHYSICS
10 Finite Element Modelling of Bandgap Engineered Graphene FET with the Application in Sensing Methanethiol Biomarker. Singh P, Abedini Sohi P, Kahrizi M 33467459
ENCS
11 Comprehensive evaluation of adsorption performances of carbonaceous materials for sulfonamide antibiotics removal. Luo B, Huang G, Yao Y, An C, Li W, Zheng R, Zhao K 32886308
CONCORDIA
12 Fabrication of Porous Gold Film Using Graphene Oxide as a Sacrificial Layer. Alazzam A, Alamoodi N, Abutayeh M, Stiharu I, Nerguizian V 31323903
ENCS

 

Title:Fabrication of Porous Gold Film Using Graphene Oxide as a Sacrificial Layer.
Authors:Alazzam AAlamoodi NAbutayeh MStiharu INerguizian V
Link:https://www.ncbi.nlm.nih.gov/pubmed/31323903?dopt=Abstract
DOI:10.3390/ma12142305
Publication:Materials (Basel, Switzerland)
Keywords:dielectrophoresisgold porousgold porous filmgraphene oxidemetal porousporousporous film
PMID:31323903 Category:Materials (Basel) Date Added:2019-08-07
Dept Affiliation: ENCS
1 Department of Mechanical Engineering, Khalifa University, Abu Dhabi 127788, United Arab Emirates. anas.alazzam@ku.ac.ae.
2 Department of Electrical Engineering, École de Technologie Supérieure, Montreal, QC H3C 1K3, Canada. anas.alazzam@ku.ac.ae.
3 Department of Chemical Engineering, Khalifa University, Abu Dhabi 127788, United Arab Emirates.
4 Mechanical Engineering Department, Arkansas State University, Jonesboro, AR 72401, USA.
5 Department of Mechanical and Industrial Engineering, Concordia University, Montreal, QC H3G 1M8, Canada.
6 Department of Electrical Engineering, École de Technologie Supérieure, Montreal, QC H3C 1K3, Canada.

Description:

Fabrication of Porous Gold Film Using Graphene Oxide as a Sacrificial Layer.

Materials (Basel). 2019 Jul 18;12(14):

Authors: Alazzam A, Alamoodi N, Abutayeh M, Stiharu I, Nerguizian V

Abstract

An original and simple fabrication process to produce thin porous metal films on selected substrates is reported. The fabrication process includes the deposition of a thin layer of gold on a substrate, spin coating of a graphene oxide dispersion, etching the gold film through the graphene oxide layer, and removing the graphene oxide layer. The porosity of the thin gold film is controlled by varying the etching time, the thickness of the gold film, and the concentration of the graphene oxide dispersion. Images by scanning electron and metallurgical microscopes show a continuous gold film with random porosity formed on the substrate with a porosity size ranging between hundreds of nanometers to tens of micrometers. This general approach enables the fabrication of porous metal films using conventional microfabrication techniques. The proposed process is implemented to fabricate electrodes with patterned porosity that are used in a microfluidic system to manipulate living cells under dielectrophoresis. Porous electrodes are found to enhance the magnitude and spatial distribution of the dielectrophoretic force.

PMID: 31323903 [PubMed]




BookR developed by Sriram Narayanan
for the Concordia University School of Health
Copyright © 2011-2026
Cookie settings
Concordia University