[1] Electrochemistry of nickel nanoparticles is controlled by surface oxide layers
YG Zhou, NV Rees, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 761-763.

[2] Room temperature ionic liquid as solvent for in situ Pd/H formation: hydrogenation of carbon-carbon double bonds
BCM Martindale, D Menshykau, S Ernst, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 1188-1197.

[3] Direct electrochemical detection and sizing of silver nanoparticles in seawater media
EJE Stuart, NV Rees, JT Cullen, RG Compton, Nanoscale, 5, (2013), 174-177.

[4] The electroreduction of benzoic acid: voltammetric observation of adsorbed hydrogen at a platinum microelectrode in room temperature ionic liquids
Y Meng, S Norman, C Hardacre, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 2031-2036.

[5] Anodic stripping voltammetry of antimony at unmodified carbon electrodes
M Lu, KE Toghill, MA Phillips, RG Compton, International Journal of Environmental Analytical Chemistry, 93, (2013), 213-227.

[6] On the meaning of the diffusion layer thickness for slow electrode reactions
A Molina, J Gonzalez, E Laborda, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 2381-2388.

[7] A Joint Experimental and Computational Search for Authentic Nano-electrocatalytic Effects: Electrooxidation of Nitrite and L-Ascorbate on Gold Nanoparticle-Modified Glassy Carbon Electrodes
Y Wang, KR Ward, E Laborda, C Salter, A Crossley, RMJ Jacobs, RG Compton, Small, 9, (2013), 478-486.

[8] Surface oxidation of gold nanoparticles supported on a glassy carbon electrode in sulphuric acid medium: contrasts with the behaviour of 'macro' gold
Y Wang, E Laborda, A Crossley, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 3133-3136.

[9] Enhancing selectivity in stripping voltammetry by different adsorption behaviors: the use of nanostructured Mg-Al-layered double hydroxides to detect Cd(II)
RX Xu, XY Yu, C Gao, JH Liu, RG Compton, XJ Huang, Analyst, 138, (2013), 1812-1818.

[10] Characterization of follow-up chemical reactions by reverse pulse voltammetry. An analytical solution for spherical electrodes and microelectrodes
A Molina, E Laborda, F Martinez-Ortiz, E Torralba, RG Compton, Electrochimica Acta, 87, (2013), 416-424.

[11] Reply to comments contained in "Are the reactions of quinones on graphite adiabatic?", by N.B. Luque, W. Schmickler [Electrochim. Acta xx (2012) yyy]
C Batchelor-McAuley, E Laborda, MC Henstridge, R Nissim, RG Compton, Electrochimica Acta, 88, (2013), 895-898.

[12] Voltammetric determination of Chromium(VI) using a gold film modified carbon composite electrode
RT Kachoosangi, RG Compton, Sensors and Actuators B - Chemical, 178, (2013), 555-562.

[13] Changed reactivity of the 1-bromo-4-nitrobenzene radical anion in a room temperature ionic liquid
S Ernst, KR Ward, SE Norman, C Hardacre, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 6382-6389.

[14] The effect of near wall hindered diffusion on nanoparticle-electrode impacts: A computational model
EO Barnes, YG Zhou, NV Rees, RG Compton, Journal of Electroanalytical Chemistry, 691, (2013), 28-34.

[15] Anomalous solubility of oxygen in acetonitrile/water mixture containing tetra-n-butylammonium perchlorate supporting electrolyte; the solubility and diffusion coefficient of oxygen in anhydrous acetonitrile and aqueous mixtures
Q Li, C Batchelor-McAuley, NS Lawrence, RS Hartshorne, RG Compton, Journal of Electroanalytical Chemistry, 688, (2013), 328-335.

[16] The rate of adsorption of nanoparticles on microelectrode surfaces
EO Barnes, RG Compton, Journal of Electroanalytical Chemistry, 693, (2013), 73-78.

[17] On the adiabaticity of electrode processes: Effect of the supporting electrolyte cation on the kinetics of electroreduction of 3-nitrophenolate
E Laborda, C Batchelor-McAuley, D Suwatchara, MC Henstridge, RG Compton, Journal of Electroanalytical Chemistry, 694, (2013), 30-36.

[18] Use of 'split waves' for the measurement of electrocatalytic kinetics: methyl viologen mediated oxygen reduction on a boron-doped diamond electrode
Q Lin, Q Li, C Batchelor-McAuley, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 7760-7767.

[19] Effects of convergent diffusion and charge transfer kinetics on the diffusion layer thickness of spherical micro- and nanoelectrodes
A Molina, E Laborda, J Gonzalez, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 7106-7113.

[20] Glassy carbon tubular electrodes for the reduction of oxygen to hydrogen peroxide
Q Li, MC Henstridge, C Batchelor-McAuley, NS Lawrence, RS Hartshorne, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 7854-7865.

[21] Nanoparticle modified electrodes can show an apparent increase in electrode kinetics due solely to altered surface geometry: The effective electrochemical rate constant for non-flat and non-uniform electrode surfaces
KR Ward, M Gara, NS Lawrence, RS Hartshorne, RG Compton, Journal of Electroanalytical Chemistry, 695, (2013), 1-9.

[22] A gold-gold oil microtrench electrode for liquid-liquid anion transfer voltammetry
SEC Dale, Y Chan, PC Bulman Page, EO Barnes, RG Compton, F Marken, Electrophoresis, 34, (2013), 1979-1984.

[23] A hydrogel modified electrode for application as a voltammetric temperature sensor and its use in oxygen detection
M Zhang, L Xiong, RG Compton, Analytical Methods, 5, (2013), 3473-3481.

[24] A theoretical and experimental approach to the adiabaticity of diffusional electron transfer processes. Electroreduction of 2-nitropropane on mercury microelectrodes
E Laborda, D Suwatchara, C Batchelor-McAuley, RG Compton, Journal of Electroanalytical Chemistry, 704, (2013), 102-110.

[25] Asymmetric Marcus-Hush theory for voltammetry
E Laborda, MC Henstridge, C Batchelor-McAuley, RG Compton, Chemical Society Reviews, 42, (2013), 4894-4905.

[26] Double potential step chronoamperometry at a microband electrode: theory and experiment
EO Barnes, L Xiong, KR Ward, RG Compton, Journal of Electroanalytical Chemistry, 701, (2013), 59-68.

[27] Dual band electrodes in generator-collector mode: Simultaneous measurement of two species
EO Barnes, GEM Lewis, SEC Dale, F Marken, RG Compton, Journal of Electroanalytical Chemistry, 703, (2013), 38-44.

[28] Electrochemical detection of chloride levels in sweat using silver nanoparticles: a basis for the preliminary screening for cystic fibrosis
HS Toh, C Batchelor-McAuley, K Tschulik, RG Compton, Analyst, 138, (2013), 4292-4297.

[29] Electrochemical Detection of NADH, Cysteine, or Glutathione Using a Caffeic Acid Modified Glassy Carbon Electrode
PT Lee, RG Compton, Electroanalysis, 25, (2013), 1613-1620.

[30] Fabrication of disposable gold macrodisc and platinum microband electrodes for use in room-temperature ionic liquids
L Xiong, D Lowinsohn, KR Ward, RG Compton, Analyst, 138, (2013), 5444-5452.

[31] Get More Out of Your Data: A New Approach to Agglomeration and Aggregation Studies Using Nanoparticle Impact Experiments
J Ellison, K Tschulik, EJE Stuart, K Jurkschat, D Omanovic, M Uhlemann, A Crossley, RG Compton, ChemistryOpen, 2, (2013), 69-75.

[32] Methyl viologen mediated oxygen reduction in ethanol solvent: the electrocatalytic reactivity of the radical cation
Q Lin, Q Li, C Batchelor-McAuley, RG Compton, Journal of Electrochemical Science and Technology, 4, (2013), 71-80.

[33] Nanomaterial modified electrodes: evaluating oxygen reduction catalysts
M Gara, KR Ward, RG Compton, Nanoscale, 5, (2013), 7304-7311.

[34] New Approach to Electrode Kinetic Measurements in Square-Wave Voltammetry: Amplitude-Based Quasireversible Maximum
V Mirceski, E Laborda, D Guziejewsk, RG Compton, Analytical Chemistry, 85, (2013), 5586-5594.

[35] Performance of silver nanoparticles in the catalysis of the oxygen reduction reaction in neutral media: Efficiency limitation due to hydrogen peroxide escape
CCM Neumann, E Laborda, K Tschulik, KR Ward, RG Compton, Nano Research, 6, (2013), 511-524.

[36] Significant changes in pKa between bulk aqueous solution and surface immobilized species: ortho-hydroquinones
PT Lee, JC Harfield, A Crossley, BS Pilgrim, RG Compton, RSC Advances, 3, (2013), 7347-7354.

[37] Superoxide generation from the reduction of oxygen at the carbon-oil-water triple phase boundary
R Nissim, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 11918-11925.

[38] Surface modification imparts selectivity, facilitating redox catalytic studies: quinone mediated oxygen reduction
J Mason, C Batchelor-McAuley, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 8362-8366.

[39] The anodic stripping voltammetry of nanoparticles: electrochemical evidence for the surface agglomeration of silver nanoparticles
HS Toh, C Batchelor-McAuley, K Tschulik, M Uhlemann, A Crossley, RG Compton, Nanoscale, 5, (2013), 4884-4893.

[40] Thin-layer vs. semi-infinite diffusion in cylindrical pores: A basis for delineating Fickian transport to identify nano-confinement effects in voltammetry
KR Ward, L Xiong, NS Lawrence, RS Hartshorne, RG Compton, Journal of Electroanalytical Chemistry, 702, (2013), 15-24.

[41] Voltammetric Determination of Iron(III) in Water
M Lu, RG Compton, Electroanalysis, 25, (2013), 1123-1129.

[42] Oxygen reduction at sparse arrays of platinum nanoparticles in aqueous acid: hydrogen peroxide as a liberated two electron intermediate
M Gara, E Laborda, P Holdway, A Crossley, JV Charles, RG Compton, Physical Chemistry Chemical Physics, 15, (2013), 19487-19495.

[43] Rate and Extent of Carbon Dioxide Uptake In Room Temperature Ionic Liquids: A New Approach Using Microdisc Electrode Voltammetry
P Li, MC Henstridge, L Xiong, RG Compton, Electroanalysis, 25, (2013), 2268-2274.

[44] 'Sticky electrodes' for the detection of silver nanoparticles
K Tschulik, RG Palgrave, C Batchelor-McAuley, RG Compton, Nanotechnology, 24, (2013), 295502-295508.

[45] A kinetic study of oxygen reduction reaction and characterization on electrodeposited gold nanoparticles of diameter between 17 nm and 40 nm in 0.5 M sulfuric acid
Y Wang, E Laborda, KR Ward, K Tschulik, RG Compton, Nanoscale, 5, (2013), 9699-9708.

[46] Evaluation of a simple disposable microband electrode device for amperometric gas sensing
L Xiong, P Goodrich, C Hardacre, RG Compton, Sensors and Actuators, B, 188, (2013), 978-987.

[47] Electrochemical detection of commercial silver nanoparticles: identification, sizing and detection in environmental media
EJE Stuart, K Tschulik, D Omanovic, JT Cullen, K Jurkschat, A Crossley, RG Compton, Nanotechnology, 24, (2013), 444002-444007.

[48] Interdigitated ring electrodes: Theory and experiment
EO Barnes, A Fernández-la-Villa, DF Pozo-Ayuso, M Castaño-Alvarez, GEM Lewis, SEC Dale, F Marken, RG Compton, Journal of Electroanalytical Chemistry, 709, (2013), 57-64.

[49] The Voltammetry and Electroanalysis of Some Estrogenic Compounds at Modified Diamond Electrodes
P Gan, RG Compton, JS Ford, Electroanalysis, 25, (2013), 2423-2434.

[50] Nanoparticle Impacts Show High-Ionic-Strength Citrate Avoids Aggregation of Silver Nanoparticles
JC Lees, J Ellison, C Batchelor-McAuley, K Tschulik, C Damm, D Omanovic, RG Compton, ChemPhysChem, 14, (2013), 3895-3897.

[51] A disposable sticky electrode for the detection of commercial silver NPs in seawater
W Cheng, EJE Stuart, K Tschulik, JT Cullen, RG Compton, Nanotechnology, 24, (2013), 505501/1-505501/6.

[52] Coulometric sizing of nanoparticles: Cathodic and anodic impact experiments open two independent routes to electrochemical sizing of Fe3O4 nanoparticles
K Tschulik, B Haddou, D Omanovic, NV Rees, RG Compton, Nano Research, 6, (2013), 836-841.

[53] Gold microelectrode ensembles: cheap, reusable and stable electrodes for the determination of arsenic (V) under aerobic conditions
EA Zakharova, GN Noskova, AS Kabakaev, NV Rees, RG Compton, International Journal of Environmental Analytical Chemistry, 93, (2013), 1105-1115.

[54] Nanocarbon Paste Electrodes
D Lowinsohn, P Gan, K Tschulik, JS Foord, RG Compton, Electroanalysis, 25, (2013), 2435-2444.

[55] Variable temperature study of electro-reduction of 3-nitrophenolate via cyclic and square wave voltammetry: Molecular insights into electron transfer processes based on the asymmetric Marcus-Hush model
E Laborda, D Suwatchara, NV Rees, MC Henstridge, A Molina, RG Compton, Electrochimica Acta, 110, (2013), 772-779.

[56] Electrochemical Sizing of Organic Nanoparticles
W Cheng, XF Zhou, RG Compton, Angewandte Chemie International Edition, 52, (2013), 12980-12982.

[57] Nanotoxicity - an electrochemist's perspective
C Batchelor-McAuley, K Tschulik, RG Compton, Portugaliae Electrochimica Acta, 31, (2013), 249-256.