An overview of recent applications of reduced graphene oxide as a basis of electroanalytical sensing platforms

被引:258
作者
Rowley-Neale, Samuel J. [1 ,2 ]
Randviir, Edward P. [1 ]
Dena, Ahmed S. Abo [3 ,4 ]
Banks, Craig E. [1 ,2 ]
机构
[1] Manchester Metropolitan Univ, Fac Sci & Engn, Chester St, Manchester M1 5GD, Lancs, England
[2] Manchester Metropolitan Univ, Manchester Fuel Cell Innovat Ctr, Chester St, Manchester M1 5GD, Lancs, England
[3] NODCAR, Giza, Egypt
[4] FUE, Fac Oral & Dent Med, New Cairo, Egypt
来源
APPLIED MATERIALS TODAY | 2018年 / 10卷
关键词
Sensing; Graphene; Reduced graphene oxide; Electrochemical; Detection; NITROGEN-DOPED GRAPHENE; BISMUTH-FILM ELECTRODE; FUNCTIONALIZED GRAPHENE; ELECTROCHEMICAL DETECTION; GOLD NANOPARTICLES; VOLTAMMETRIC DETERMINATION; SILVER NANOPARTICLES; AQUEOUS DISPERSIONS; METHYLENE-BLUE; GRAPHITE OXIDE;
D O I
10.1016/j.apmt.2017.11.010
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The academic literature using graphene within the field of electrochemistry is substantial. Graphene can be fabricated via a plethora of routes with each having its own unique merits (e.g. cost, fabrication time, quality and scale) and reduced graphene oxide (rGO) is more often the material of choice for electrochemical sensors and associated applications due to its ease of fabrication and ability to be mass produced on the kilogram scale. This review overviews pertinent developments in the use of rGO as the basis of electroanalytical sensors (2016-2017); guidelines for the progression of this field are also given. (c) 2017 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license.
引用
收藏
页码:218 / 226
页数:9
相关论文
共 88 条
[1]   A novel glucose sensor using lutetium phthalocyanine as redox mediator in reduced graphene oxide conducting polymer multifunctional hydrogel [J].
Al-Sagur, H. ;
Komathi, S. ;
Khan, M. A. ;
Gurek, A. G. ;
Hassan, A. .
BIOSENSORS & BIOELECTRONICS, 2017, 92 :638-645
[2]   A non-enzymatic amperometric hydrogen peroxide sensor based on iron nanoparticles decorated reduced graphene oxide nanocomposite [J].
Amanulla, Baishnisha ;
Palanisamy, Selvakumar ;
Chen, Shen-Ming ;
Velusamy, Vijayalakshmi ;
Chiu, Te-Wei ;
Chen, Tse-Wei ;
Ramaraj, Sayee Kannan .
JOURNAL OF COLLOID AND INTERFACE SCIENCE, 2017, 487 :370-377
[3]   Electrochemistry at Chemically Modified Graphenes [J].
Ambrosi, Adriano ;
Bonanni, Alessandra ;
Sofer, Zdenek ;
Cross, Jeffrey S. ;
Pumera, Martin .
CHEMISTRY-A EUROPEAN JOURNAL, 2011, 17 (38) :10763-10770
[4]   On Oxygen-Containing Groups in Chemically Modified Graphenes [J].
Bonanni, Alessandra ;
Ambrosi, Adriano ;
Pumera, Martin .
CHEMISTRY-A EUROPEAN JOURNAL, 2012, 18 (15) :4541-4548
[5]   A hydrogen peroxide sensor based on TNM functionalized reduced graphene oxide grafted with highly monodisperse Pd nanoparticles [J].
Bozkurt, Sait ;
Tosun, Berna ;
Sen, Betul ;
Akocak, Suleyman ;
Savk, Aysun ;
Ebeoglugil, Mehmet Faruk ;
Sen, Fatih .
ANALYTICA CHIMICA ACTA, 2017, 989 :88-94
[6]  
Brodie B. C., 1997, PHILOS T R SOC LONDO, V149, P249, DOI 10.1098/rstl.1859.0013
[7]  
Brownson D.A. C., 2014, HDB GRAPHENE ELECTRO
[8]   Graphene oxide electrochemistry: the electrochemistry of graphene oxide modified electrodes reveals coverage dependent beneficial electrocatalysis [J].
Brownson, Dale A. C. ;
Smith, Graham C. ;
Banks, Craig E. .
ROYAL SOCIETY OPEN SCIENCE, 2017, 4 (11)
[9]   Electrochemical properties of CVD grown pristine graphene: monolayer- vs. quasi-graphene [J].
Brownson, Dale A. C. ;
Varey, Sarah A. ;
Hussain, Fiazal ;
Haigh, Sarah J. ;
Banks, Craig E. .
NANOSCALE, 2014, 6 (03) :1607-1621
[10]   Graphene electrochemistry: fundamental concepts through to prominent applications [J].
Brownson, Dale A. C. ;
Kampouris, Dimitrios K. ;
Banks, Craig E. .
CHEMICAL SOCIETY REVIEWS, 2012, 41 (21) :6944-6976
123456789