Papers

[1] Simulated low-support voltammetry: Deviations from Ohm's Law
C Batchelor-McAuley, K Ngamchuea, RG Compton, Journal of Electroanalytical Chemistry, 830, (2018), 88-94.

[2] Anodic stripping voltammetry of silver in the absence of electrolytes: Theory and experiment
K Ngamchuea, C Batchelor-McAuley, RG Compton, Journal of Electroanalytical Chemistry, 830-831, (2018), 122-130.

[3] Understanding gold nanoparticle dissolution in cyanide-containing solution via impact-chemistry
A Suherman, G Zampardi, S Kuss, E Tanner, Hatem Amin, N Young, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 28300-28307.

[4] A nano-carbon electrode optimized for adsorptive stripping voltammetry: Application to detection of the stimulant selegiline in authentic saliva
W Santos, Hatem Amin, RG Compton, Sensors and Actuators B: Chemical, 279, (2018), 433-439.

[5] Theoretical prediction of a transient accumulation of nanoparticles at a well-defined distance from an electrified liquid-solid interface
C Chan, E Kätelhön, RG Compton, Nanoscale, 10, (2018), 19459-19468.

[6] Simultaneous activity and surface area measurements on single mesoporous nanoparticle aggregates
J Xue, C Batchelor-McAuley, N Young, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 23847-23850.

[7] Electrolyte-Induced Electrical Disconnection between Single Graphene Nanoplatelets and an Electrode
A Krittayavathananon, X Li, C Batchelor-McAuley, M Sawangphruk, RG Compton, The Journal of Physical Chemistry Letters, 19, (2018), 5822-5826.

[8] Detection of Escherichia coli bacteria by impact electrochemistry
R Couto, L Chen, S Kuss, RG Compton, Analyst, 143, (2018), 4840-4843.

[9] Electrochemical Detection of Pathogenic Bacteria-Recent Strategies, Advances and Challenges
S Kuss, Hatem Amin, RG Compton, Chemistry - An Asian Journal, 19, (2018), 2758-2769.

[10] Spectroscopy takes electrochemistry beyond the interface: A compact analytical solution for the reversible first-order catalytic mechanism
E Laborda, J.M Gómez-Gil, A Molina, RG Compton, Electrochimica Acta, 284, (2018), 721-732.

[11] Electrochemical Behavior of Single CuO Nanoparticles: Implications for the Assessment of their Environmental Fate
G Zampardi, J Thöming, H Naatz, H Amin, S Pokhrel, L Mädler, RG Compton, Small, 14, (2018), 1801765.

[12] Shape and size of non-spherical silver nanoparticles: implications for calculating nanoparticle number concentrations
C Little, C Batchelor-McAuley, N Young, RG Compton, Nanoscale, 10, (2018), 15943 -15947.

[13] Tafel analysis in practice
D Li, C Lin, C Batchelor-McAuley, L Chen, RG Compton, Journal of Electroanalytical Chemistry, 826, (2018), 117 -124.

[14] A New Composite Electrode Applied for Studying the Electrochemistry of Insoluble Particles: alpha-HgS
M Yang, RG Compton, Chemistry-A European Journal, 24, (2018), 10208 -10215.

[15] Natural convection effects in electrochemical systems
J Novev, RG Compton, Current Opinion in Electrochemistry, 7, (2018), 118-129.

[16] Electroanalytical study of dopamine oxidation on carbon electrodes: from the macro- to the micro-scale
C Lin, L Chen, E Tanner, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 148-157.

[17] Impact electrochemistry reveals that graphene nanoplatelets catalyse the oxidation of dopamine via adsorption
L Chen, E Tanner, C Lin, RG Compton, Chemical Science, 9, (2018), 152-159.

[18] Chemical analysis in saliva and the search for salivary biomarkers - a tutorial review
K Ngamchuea, K Chaisiwamongkhol, C Batchelor-McAuley, RG Compton, Analyst, 143, (2018), 81-99.

[19] Nafion particles doped with methyl viologen: electrochemistry
H Yang, X Li, C Batchelor-McAuley, S Sokolov, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 682-689.

[20] The solution phase aggregation of graphene nanoplates
A Krittayavathananon, X Li, S Sokolov, C Batchelor-McAuley, M Sawangphruk, RG Compton, Applied Materials Today, 10, (2018), 122-126.

[21] The mechanism of electrochemical reduction of hydrogen peroxide on silver nanoparticles
X Cai, E Tanner, C Lin, K Ngamchuea, J Foord, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 1608-1614.

[22] Individual Detection and Characterization of Non-Electrocatalytic, Redox-Inactive Particles in Solution by using Electrochemistry
E Laborda, A Molina, C Batchelor-McAuley, RG Compton, ChemElectroChem, 5, (2018), 410-417.

[23] Nanoscopic carbon electrodes: Structure, electrical properties and application for electrochemistry
EM Akinoglu, E Kätelhön, J Pampel, Z Ban, M Antonietti, RG Compton, M Giersig, Carbon, 130, (2018), 768-774.

[24] Understanding electroanalytical measurements in authentic human saliva leading to the detection of salivary uric acid
K Ngamchuea, C Batchelor-McAuley, RG Compton, Sensors and Actuators B: Chemical, 262, (2018), 404-410.

[25] Cyclic voltammetry with non-triangular waveforms: Electrochemically irreversible and quasi-reversible systems
Y Uchida, E Kätelhön, RG Compton, Journal of Electroanalytical Chemistry, 810, (2018), 135-144.

[26] Non-triangular potential sweep cyclic voltammetry of reversible electron transfer: Experiment meets theory
H Amin, Y Uchida, C Batchelor-McAuley, E Kätelhön, RG Compton, Journal of Electroanalytical Chemistry, 815, (2018), 24-29.

[27] Voltammetric determination of aluminium(III) at tannic acid capped-gold nanoparticle modified electrodes
A Suherman, E Tanner, S Kuss, S Sokolov, J Holter, N Young, RG Compton, Sensors and Actuators B: Chemical, 265, (2018), 682-690.

[28] Electrochemical Hg2+ detection at tannic acid-gold nanoparticle modified electrodes by square wave voltammetry
A Suherman, S Kuss, E Tanner, N Young, RG Compton, Analyst, 143, (2018), 2035-2041.

[29] The fate of silver nanoparticles in authentic human saliva
K Ngamchuea, C Batchelor-McAuley, RG Compton, Nanotoxicology, 12, (2018), 305-311.

[30] A thermostated cell for electrochemistry: minimising natural convection and investigating the role of evaporation and radiation
X Li, C Batchelor-McAuley, J Novev, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 11794-11804.

[31] Linear sweep voltammetry with non-triangular waveforms: New opportunities in electroanalysis
Y Uchida, E Kätelhön, RG Compton, Journal of Electroanalytical Chemistry, 818, (2018), 140-148.

[32] Comparing the effect of different surfactants on the aggregation and electrical contact properties of graphene nanoplatelets
A Krittayavathananon, X Li, C Batchelor-McAuley, M Sawangphruk, RG Compton, Applied Materials Today, 12, (2018), 163-167.

[33] Electrochemistry of Single Enzymes: Fluctuations of Catalase Activities
C Lin, L Sepunaru, E Kätelhön, RG Compton, Journal of Physical Chemistry Letters, 9, (2018), 2814-2817.

[34] A quantitative methodology for the study of particle-electrode impacts
C Little, R Xie, C Batchelor-McAuley, E Kätelhön, X Li, N Young, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 13537-13546.

[35] Singlet Oxygen and the Origin of Oxygen Functionalities on the Surface of Carbon Electrodes
K Chaisiwamongkhol, C Batchelor-McAuley, R Palgrave, RG Compton, Angewandte Chemie, 57, (2018), 6270-6273.

[36] Coupled Optical and Electrochemical Probing of Silver Nanoparticle Destruction in a Reaction Layer
C Little, C Batchelor-McAuley, K Ngamchuea, C Lin, N Young, RG Compton, ChemistryOpen, 7, (2018), 370-380.

[37] Quantifying the Polymeric Capping of Nanoparticles with X-Ray Photoelectron Spectroscopy
E Tanner, S Sokolov, K Ngamchuea, R Palgrave, RG Compton, ChemPhysChem, 19, (2018), 1341-1343.

[38] Salivary glutathione in bipolar disorder: A pilot study
K Ngamchuea, C Batchelor-McAuley, C Batchelor-McAuley, C Williams, B Godlewska, A Sharpley, P Cowen, RG Compton, Journal of Affective Disorders, 238, (2018), 277-280.

[39] Role of Nanomorphology and Interfacial Structure of Platinum Nanoparticles in Catalyzing the Hydrogen Oxidation Reaction
X Jiao, C Batchelor-McAuley, C Lin, E Kätelhön, E Tanner, N Young, RG Compton, ACS Catalysis, 8, (2018), 6192-6202.

[40] Single entity electrocatalysis: oxygen reduction mediated via methyl viologen doped Nafion nanoparticles
L Chen, C Lin, RG Compton, Physical Chemistry Chemical Physics, 20, (2018), 15795-15806.

[41] Linear sweep voltammetry with non-triangular waveforms at a microdisc electrode
Y Uchida, E Kätelhön, RG Compton, Journal of Electroanalytical Chemistry, 823, (2018), 465-473.

[42] Particle-electrode impacts: Evidencing partial versus complete oxidation via variable temperature studies
C Little, X Li, C Batchelor-McAuley, N Young, RG Compton, Journal of Electroanalytical Chemistry, 823, (2018), 492-498.

[43] Analytical solutions for the study of homogeneous first-order chemical kinetics via UV-vis spectroelectrochemistry
A Molina, E Laborda, J Gómez-Gil, F Martínez-Ortiz, RG Compton, Journal of Electroanalytical Chemistry, 819, (2018), 202-213.

[44] How can Electrode Surface Modification Benefit Electroanalysis?
E Tanner, RG Compton, Electroanalysis, 30, (2018), 1336-1341.