| Understanding voltammetry RG Compton, CE Banks World Scientific, 2018 | 1306 | 2018 |
| Metal nanoparticles and related materials supported on carbon nanotubes: methods and applications GG Wildgoose, CE Banks, RG Compton Small 2 (2), 182-193, 2006 | 1052 | 2006 |
| Electrocatalysis at graphite and carbon nanotube modified electrodes: edge-plane sites and tube ends are the reactive sites CE Banks, TJ Davies, GG Wildgoose, RG Compton Chemical Communications, 829-841, 2005 | 910 | 2005 |
| An overview of graphene in energy production and storage applications DAC Brownson, DK Kampouris, CE Banks Journal of Power Sources 196 (11), 4873-4885, 2011 | 891 | 2011 |
| Carbon quantum dots and their derivative 3D porous carbon frameworks for sodium‐ion batteries with ultralong cycle life H Hou, CE Banks, M Jing, Y Zhang, X Ji Advanced materials 27 (47), 7861-7866, 2015 | 776 | 2015 |
| Carbon nanotubes contain metal impurities which are responsible for the “electrocatalysis” seen at some nanotube‐modified electrodes CE Banks, A Crossley, C Salter, SJ Wilkins, RG Compton Angewandte Chemie International Edition 45 (16), 2533-2537, 2006 | 627 | 2006 |
| Analytical methods for the determination of pharmaceuticals in aqueous environmental samples TA Ternes TrAC Trends in Analytical Chemistry 20 (8), 419-434, 2001 | 614 | 2001 |
| New electrodes for old: from carbon nanotubes to edge plane pyrolytic graphite CE Banks, RG Compton Analyst 131 (1), 15-21, 2006 | 599 | 2006 |
| Graphene electrochemistry: fundamental concepts through to prominent applications DAC Brownson, DK Kampouris, CE Banks Chemical Society Reviews 41 (21), 6944-6976, 2012 | 568 | 2012 |
| Basal plane pyrolytic graphite modified electrodes: comparison of carbon nanotubes and graphite powder as electrocatalysts RR Moore, CE Banks, RG Compton Analytical chemistry 76 (10), 2677-2682, 2004 | 552 | 2004 |
| Graphene electrochemistry: an overview of potential applications DAC Brownson, CE Banks Analyst 135 (11), 2768-2778, 2010 | 517 | 2010 |
| New directions in screen printed electroanalytical sensors: an overview of recent developments JP Metters, RO Kadara, CE Banks Analyst 136 (6), 1067-1076, 2011 | 416 | 2011 |
| Silver nanoparticle assemblies supported on glassy-carbon electrodes for the electro-analytical detection of hydrogen peroxide CM Welch, CE Banks, AO Simm, RG Compton Analytical and bioanalytical chemistry 382 (1), 12-21, 2005 | 413 | 2005 |
| A decade of graphene research: production, applications and outlook EP Randviir, DAC Brownson, CE Banks Materials Today 17 (9), 426-432, 2014 | 405 | 2014 |
| Exploring the electrocatalytic sites of carbon nanotubes for NADH detection: an edge plane pyrolytic graphite electrode study CE Banks, RG Compton Analyst 130 (9), 1232-1239, 2005 | 405 | 2005 |
| Chemically modified carbon nanotubes for use in electroanalysis GG Wildgoose, CE Banks, HC Leventis, RG Compton Microchimica Acta 152 (3-4), 187-214, 2006 | 404 | 2006 |
| Iron oxide particles are the active sites for hydrogen peroxide sensing at multiwalled carbon nanotube modified electrodes B Šljukić, CE Banks, RG Compton Nano letters 6 (7), 1556-1558, 2006 | 392 | 2006 |
| Electrochemical impedance spectroscopy: an overview of bioanalytical applications EP Randviir, CE Banks Analytical Methods 5 (5), 1098-1115, 2013 | 361 | 2013 |
| Investigation of modified basal plane pyrolytic graphite electrodes: definitive evidence for the electrocatalytic properties of the ends of carbon nanotubes CE Banks, RR Moore, TJ Davies, RG Compton Chemical Communications, 1804-1805, 2004 | 360 | 2004 |
| The handbook of graphene electrochemistry DAC Brownson, CE Banks Springer 201, 126, 2014 | 272 | 2014 |
