Papers

[1] Electrochemical studies of silver nanoparticles: a guide for experimentalists and a perspective
K Tschulik, C Batchelor-McAuley, HS Toh, EJE Stuart, RG Compton, Physical Chemistry Chemical Physics, 16, (2014), 616-623.

[2] Simple Analytical Equations for the Current-Potential Curves at Microelectrodes: A Universal Approach
A Molina, J Gonzalez, EO Barnes, RG Compton, Journal of Physical Chemistry C, 118, (2014), 346-356.

[3] A dual-plate ITO-ITO generator-collector microtrench sensor: surface activation, spatial separation and suppression of irreversible oxygen and ascorbate interference
MA Hasnat, AJ Gross, SEC Dale, EO Barnes, RG Compton, F Marken, Analyst, 139, (2014), 569-575.

[4] The Marcus-Hush model of electrode kinetics at a single nanoparticle
MC Henstridge, KR Ward, RG Compton, Journal of Electroanalytical Chemistry, 712, (2014), 14-18.

[5] A proof-of-concept - Using pre-created nucleation centres to improve the limit of detection in anodic stripping voltammetry
HS Toh, C Batchelor-McAuley, K Tschulik, C Damm, RG Compton, Sensors and Actuators B, 193, (2014), 315-319.

[6] The strong catalytic effect of Pb(II) on the oxygen reduction reaction on 5 nm gold nanoparticles
Y Wang, E Laborda, BJ Plowman, K Tschulik, KR Ward, RG Palgrave, C Damm, RG Compton, Physical Chemistry Chemical Physics, 16, (2014), 3200-3208.

[7] Koutecky-Levich analysis applied to nanoparticle modified rotating disk electrodes: Electrocatalysis or misinterpretation?
J Masa, C Batchelor-McAuley, W Schuhmann, RG Compton, Nano Research, 7, (2014), 71-78.

[8] The electrochemical reduction of 1-bromo-4-nitrobenzene at zinc electrodes in a room-temperature ionic liquid: a facile route for the formation of arylzinc compounds
S Ernst, SE Norman, C Hardacre, RG Compton, Physical Chemistry Chemical Physics, 16, (2014), 4478-4482.

[9] Equality of diffusion-limited chronoamperometric currents to equal area spherical and cubic nanoparticles on a supporting electrode surface
E Kätelhön, EO Barnes, KJ Krause, B Wolfrum, RG Compton, Chemical Physics Letters, 595, (2014), 31-34.

[10] Why are silver nanoparticles more toxic than bulk silver? Towards understanding the dissolution and toxicity of silver nanoparticles
C Batchelor-McAuley, K Tschulik, CCM Neumann, E Laborda, RG Compton, International Journal of Electrochemical Science, 9, (2014), 1132-1138.

[11] Electrochemical Detection of Glutathione Using a Poly(caffeic acid) Nanocarbon Composite Modified Electrode
Lee PT, KR Ward, K Tschulik, G Chapman, RG Compton, Electroanalysis, 26, (2014), 366-373.

[12] Improving the Rate of Silver Nanoparticle Adhesion to `Sticky Electrodes': Stick and Strip Experiments at a DMSA-Modified Gold Electrode
EJE Stuart, K Tschulik, J Ellison, RG Compton, Electroanalysis, 26, (2014), 285-291.

[13] The Measurement of the Gibbs Energy of Transfer Between Oil and Water Using a Nano-Carbon Paste Electrode
P Gan, D Lowinsohn, JS Foord, RG Compton, Electroanalysis, 26, (2014), 351-358.

[14] Electrochemical Detection and Characterisation of Polymer Nanoparticles
XF Zhou, W Cheng, C Batchelor-McAuley, K Tschulik, RG Compton, Electroanalysis, 26, (2014), 248-253.

[15] Gold electrodes from recordable CDs for the sensitive, semi-quantitative detection of commercial silver nanoparticles in seawater media
EJE Stuart, K Tschulik, D Lowinsohn, JT Cullen, RG Compton, Sensors and Actuators B, 195, (2014), 213-229.

[16] Extending the Curtin-Hammett principle: the relative rates of intramolecular cyclisation versus intermolecular processes
MC Henstridge, SG Davies, JE Thomson, RG Compton, Tetrahedron Letters, 55, (2014), 1886-1889.

[17] Nanoparticles in sensing applications: on what timescale do analyte species adsorb on the particle surface?
E Kätelhön, RG Compton, Analyst, 139, (2014), 2411-2415.

[18] Voltammetric pH sensor based on an edge plane pyrolytic graphite electrode
M Lu, RG Compton, Analyst, 139, (2014), 2397-2403.

[19] Nano-Litre Proton/Hydrogen Titration in a Dual-Plate Platinum-Platinum Generator-Collector Electrode Micro-Trench
SEC Dale, A Vuorema, M Sillanpää, J Weber, AJ Wain, EO Barnes, RG Compton, F Marken, Electrochimica Acta, 125, (2014), 94-100.

[20] Simultaneous electrochemical and 3D optical imaging of silver nanoparticle oxidation
C Batchelor-McAuley, A Martinez-Marrades, K Tschulik, AN Patel, C Combellas, F Kanoufi, G Tessier, RG Compton, Chemical Physics Letters, 597, (2014), 20-25.

[21] An approximate theoretical treatment of ion transfer processes at asymmetric microscopic and nanoscopic liquid-liquid interfaces: Single and double potential pulse techniques
A Molina, E Laborda, RG Compton, Chemical Physics Letters, 597, (2014), 126-133.

[22] How Many Molecules are Required to Obtain a Steady Faradaic Current from Mediated Electron Transfer at a Single Nanoparticle on a Supporting Surface?
E Kätelhön, KJ Krause, B Wolfrum, RG Compton, ChemPhysChem, 15, (2014), 872-875.

[23] Organic Nanoparticles: Mechanism of Electron Transfer to Indigo Nanoparticles
W Cheng, C Batchelor-McAuley, RG Compton, ChemElectroChem, 1, (2014), 714-717.

[24] Nonenzymatic Electrochemical Superoxide Sensor
R Nissim, RG Compton, ChemElectroChem, 1, (2014), 763-771.

[25] Defining the transfer coefficient in electrochemistry: An assessment (IUPAC Technical Report)
R Guidelli, RG Compton, JM Feliu, E Gileadi, J Lipkowski, W Schmickler, S Trasatti, Pure and Applied Chemistry, 86, (2014), 245-258.

[26] Definition of the transfer coefficient in electrochemistry (IUPAC Recommendations 2014)
R Guidelli, RG Compton, JM Feliu, E Gileadi, J Lipkowski, W Schmickler, S Trasatti, Pure and Applied Chemistry, 86, (2014), 259-262.

[27] Electrochemical detection of nanoparticles by 'nano-impact' methods
W Cheng, RG Compton, Trends in Analytical Chemistry, 58, (2014), 79-89.

[28] Voltammetry at porous electrodes: A theoretical study
EO Barnes, X Chen, P Li, RG Compton, Journal of Electroanalytical Chemistry, 720, (2014), 92-100.

[29] Nano-impacts of bifunctional organic nanoparticles
XF Zhou, W Cheng, RG Compton, Nanoscale, 6, (2014), 6873-6878.

[30] Shielding of a Microdisc Electrode Surrounded by an Adsorbing Surface
S Eloul, RG Compton, ChemElectroChem, 1, (2014), 917-924.

[31] Heterogeneous Catalysis of Multiple-Electron-Transfer Reactions at Nanoparticle-Modified Electrodes
E Laborda, CCM Neumann, Y Wang, KR Ward, A Molina, RG Compton, ChemElectroChem, 1, (2014), 909-916.

[32] The selective electrochemical detection of homocysteine in the presence of glutathione, cysteine, and ascorbic acid using carbon electrodes
PT Lee, D Lowinsohn, RG Compton, Analyst, 139, (2014), 3755-3762.

[33] Nanoparticle impacts reveal magnetic field induced agglomeration and reduced dissolution rates
K Tschulik, RG Compton, Physical Chemistry Chemical Physics, 16, (2014), 13909-13913.

[34] Amperometric detection of oxygen under humid conditions: The use of a chemically reactive room temperature ionic liquid to 'trap' superoxide ions and ensure a simple one electron reduction
L Xiong, EO Barnes, RG Compton, Sensors and Actuators B, 200, (2014), 157-166.

[35] The use of cylindrical micro-wire electrodes for nano-impact experiments; facilitating the sub-picomolar detection of single nanoparticles
J Ellison, C Batchelor-McAuley, K Tschulik, RG Compton, Sensors and Actuators B, 200, (2014), 47-52.

[36] Quantifying the apparent 'Catalytic' effect of porous electrode surfaces
K Ward, RG Compton, Journal of Electroanalytical Chemistry, 724, (2014), 43-47.

[37] Electrochemical Detection of Melamine
J Xue, PT Lee, RG Compton, Electroanalysis, 26, (2014), 1454-1460.

[38] Simultaneous Detection of Homocysteine and Cysteine in the Presence of Ascorbic Acid and Glutathione Using a Nanocarbon Modified Electrode
PT Lee, D Lowinsohn, RG Compton, Electroanalysis, 26, (2014), 1488-1496.

[39] Nanoparticle-Impact Experiments are Highly Sensitive to the Presence of Adsorbed Species on Electrode Surfaces
E Kätelhön, W Cheng, C Batchelor-McAuley, K Tschulik, RG Compton, ChemElectroChem, 1, (2014), 1057-1062.

[40] Inhibition of Cu Underpotential Deposition on Au Nanoparticles: The Role of the Citrate Capping Agent and Nanoparticle Size
BJ Plowman, RG Compton, ChemElectroChem, 1, (2014), 1009-1012.

[41] One electron oxygen reduction in room temperature ionic liquids: A comparative study of Butler-Volmer and Symmetric Marcus-Hush theories using microdisc electrodes
EEL Tanner, L Xiong, EO Barnes, RG Compton, Journal of Electroanalytical Chemistry, 727, (2014), 59-68.

[42] Electrochemical quantification of iodide ions in synthetic urine using silver nanoparticles: a proof-of-concept
HS Toh, K Tschulik, C Batchelor-McAuley, RG Compton, Analyst, 139, (2014), 3986-3990.

[43] A flow system for hydrogen peroxide production at reticulated vitreous carbon via electroreduction of oxygen
Q Li, C Batchelor-McAuley, NS Lawrence, RS Hartshorne, CJV Jones, RG Compton, Journal of Solid State Electrochemistry, 18, (2014), 1215-1221.

[44] The use of screen-printed electrodes in a proof of concept electrochemical estimation of homocysteine and glutathione in the presence of cysteine using catechol
PT Lee, RG Compton, D Lowinsohn, Sensors, 14, (2014), 10395-10411.

[45] Cyclic and Square-Wave Voltammetry at Diffusionally Asymmetric Microscopic and Nanoscopic Liquid-Liquid Interfaces: A Simple Theoretical Approach
A Molina, E Laborda, RG Compton, Journal of Physical Chemistry C, 118, (2014), 18249-18256.

[46] Towards detection of total antioxidant concentrations of glutathione, cysteine, homocysteine and ascorbic acid using a nanocarbon paste electrode
D Lowinsohn, PT Lee, RG Compton, International Journal of Electrochemical Science, 9, (2014), 3458-3472.

[47] A Critical Evaluation of the Interpretation of Electrocatalytic Nanoimpacts
L Ly, C Batchelor-McAuley, K Tschulik, E Kätelhön, RG Compton, Journal of Physical Chemistry C, 118, (2014), 17756-17763.

[48] Use of the capping agent for the electrochemical detection and quantification of nanoparticles: CdSe quantum dots
HG Hepburn, C Batchelor-McAuley, K Tschulik, RT Kachoosangi, D Ness, RG Compton, Sensors and Actuators, B, 204, (2014), 445-449.

[49] Cavity transport effects in generator-collector electrochemical analysis of nitrobenzene
GEM Lewis, SEC Dale, B Kasprzyk-Hordern, AT Lubben, EO Barnes, RG Compton, F Marken, Physical Chemistry Chemical Physics, 16, (2014), 18966-18973.

[50] Chemical interactions between silver nanoparticles and thiols: a comparison of mercaptohexanol against cysteine
HS Toh, C Batchelor-McAuley, K Tschulik, RG Compton, Science China: Chemistry, 57, (2014), 1199-1210.

[51] Diffusional transport to and through thin-layer nanoparticle film modified electrodes: capped CdSe nanoparticle modified electrodes
HG Hepburn, C Batchelor-McAuley, K Tschulik, EO Barnes, RT Kachoosangi, RG Compton, Physical Chemistry Chemical Physics, 16, (2014), 18034-18041.

[52] Electrochemical observation of single collision events: fullerene nanoparticles
EJE Stuart, K Tschulik, C Batchelor-McAuley, RG Compton, ACS Nano, 8, (2014), 7648-7654.

[53] Voltammetric pH sensing using carbon electrodes: glassy carbon behaves similarly to EPPG
M Lu, RG Compton, Analyst, 139, (2014), 4599-4605.

[54] Ionic Liquid-Carbon Nanotube Modified Screen-Printed Electrodes and Their Potential for Adsorptive Stripping Voltammetry
P Gan, JS Foord, RG Compton, Electroanalysis, 26, (2014), 1886-1892.

[55] Strong negative nanocatalysis: oxygen reduction and hydrogen evolution at very small (2 nm) gold nanoparticles
Y Wang, E Laborda, K Tschulik, C Damm, A Molina, RG Compton, Nanoscale, 6, (2014), 11024-11030.

[56] Sensing with nanopores - the influence of asymmetric blocking on electrochemical redox cycling current
KJ Krause, E Kätelhön, SG Lemay, RG Compton, B Wolfrum, Analyst, 139, (2014), 5499-5503.

[57] Proof of Concept of the Electrochemical Sensing of 3-Iodothyronamine (T1AM) and Thyronamine (T0AM)
LM Gonçalves, MM Moreira, CF Azevedo, IM Valente, JC Sousa, TS Scanlan, RG Compton, JA Rodrigues, ChemElectroChem, 1, (2014), 1623-1626.

[58] The surface energy of single nanoparticles probed via anodic stripping voltammetry
CCM Neumann, C Batchelor-McAuley, K Tschulik, HS Toh, P Shumbula, J Pillay, R Tshikhudo, RG Compton, ChemElectroChem, 1, (2014), 87-89.

[59] Introducing absorptive stripping voltammetry: wide concentration range voltammetric phenol detection
R Nissim, RG Compton, Analyst, 139, (2014), 5911-5918.

[60] Understanding nano-impacts: impact times and near-wall hindered diffusion
E Kätelhön, RG Compton, Chemical Science, 5, (2014), 4592-4598.

[61] Voltammetric Sensitivity Enhancement by Using Preconcentration Adjacent to the Electrode: Simulation, Critical Evaluation, and Insights
S Eloul, RG Compton, Journal of Physical Chemistry C, 118, (2014), 24520-24532.

[62] Doping of Single Polymeric Nanoparticles
XF Zhou, W Cheng, RG Compton, Angewandte Chemie, International Edition, 53, (2014), 12587-12589.

[63] Electrocatalytic detection of glutathione - the search for new mediators
D Lowinsohn, PT Lee, RG Compton, Journal of the Brazilian Chemical Society, 25, (2014), 1614-1620.

[64] Amperometric gas detection: a review
L Xiong, RG Compton, International Journal of Electrochemical Science, 9, (2014), 7152-7181.

[65] Investigation of Single-Drug-Encapsulating Liposomes using the Nano-Impact Method
W Cheng, RG Compton, Angewandte Chemie, International Edition, 53, (2014), 13928-13930.

[66] Planar diffusion to macro disc electrodes-what electrode size is required for the Cottrell and Randles-Sevcik equations to apply quantitatively
K Ngamchuea, S Eloul, K Tschulik, RG Compton, Journal of Solid State Electrochemistry, 18, (2014), 3251-3257.

[67] Thin film-modified electrodes: a model for the charge transfer resistance in electrochemical impedance spectroscopy
S Eloul, C Batchelor-McAuley, RG Compton, Journal of Solid State Electrochemistry, 18, (2014), 3239-3243.

[68] Thin-Film Modified Rotating Disk Electrodes: Models of Electron-Transfer Kinetics for Passive and Electroactive Films
C Batchelor-McAuley, RG Compton, Journal of Physical Chemistry C, 118, (2014), 30034-30038.