Your search keyword '"Macpherson, Julie V."' showing total 41 results

1. Simulation of the cyclic voltammetric response of an outer-sphere redox species with inclusion of electrical double layer structure and ohmic potential drop.

Author

Levey, Katherine J., Edwards, Martin A., White, Henry S., and Macpherson, Julie V.

Abstract

A finite-element model has been developed to simulate the cyclic voltammetric (CV) response of a planar electrode for a 1e outer-sphere redox process, which fully accounts for cell electrostatics, including ohmic potential drop, ion migration, and the structure of the potential-dependent electric double layer. Both reversible and quasi-reversible redox reactions are treated. The simulations compute the time-dependent electric potential and ion distributions across the entire cell during a voltammetric scan. In this way, it is possible to obtain the interdependent faradaic and non-faradaic contributions to a CV and rigorously include all effects of the electric potential distribution on the rate of electron transfer and the local concentrations of the redox species Oz and Rz−1. Importantly, we demonstrate that the driving force for electron transfer can be different to the applied potential when electrostatic interactions are included. We also show that the concentrations of Oz and Rz−1 at the plane of electron transfer (PET) significantly depart from those predicted by the Nernst equation, even when the system is characterised by fast electron transfer/diffusion control. A mechanistic rationalisation is also presented as to why the electric double layer has a negligible effect on the CV response of such reversible systems. In contrast, for quasi-reversible electron transfer the concentrations of redox species at the PET are shown to play an important role in determining CV wave shape, an effect also dependant on the charge of the redox species and the formal electrode potential of the redox couple. Failure to consider electrostatic effects could lead to incorrect interpretation of electron-transfer kinetics from the CV response. Simulated CVs at scan rates between 0.1 and 1000 V s−1 are found to be in good agreement with experimental data for the reduction of 1.0 mM Ru(NH3)63+ at a 2 mm diameter gold disk electrode in 1.0 M potassium nitrate. [ABSTRACT FROM AUTHOR]

Published

2023

2. Atomic-scale investigation of the reversible α- to ω-phase lithium ion charge -- discharge characteristics of electrodeposited vanadium pentoxide nanobelts.

Author

Hussein, Haytham E. M., Beanland, Richard, Sànchez, Ana M., Walker, David, Walker, Marc, Yisong Han, and Macpherson, Julie V.

Abstract

Using an electrochemical potential pulse methodology in a mixed solvent system, electrochemical deposition of amorphous vanadium pentoxide (V2O5) nanobelts is possible. Crystallisation of the material is achieved using in air annealing with the temperature of crystallisation identified using in situ heating transmission electron microscopy (TEM). The resulting α-phase V2O5 nanobelts have typical thicknesses of 10-20 nm, widths and lengths in the range 5-37 nm (mean 9 nm) and 15-221 nm (mean 134 nm), respectively. One-cycle reversibility studies for lithium intercalation (discharge) and de-intercalation (charge) reveal a maximum specific capacity associated with three lithium ions incorporated per unit cell, indicative of ω-Li3V2O5 formation. Aberration corrected scanning TEM confirm the formation of ω-Li3V2O5 across the entirety of a nanobelt during discharge and also the reversible formation of the α-V2O5 phase upon full charge. Preliminary second cycle studies reveal reformation of the ω-Li3V2O5, accompanied with a morphological change in the nanobelt dimensions. Achieving α-V2O5 to ω-Li3V2O5 to α-V2O5 reversibility is extremely challenging given the large structural rearrangements required. This phenomenon has only been seen before in a very limited number of studies, mostly employing nanosized V2O5 materials and never before with electrodeposited material. [ABSTRACT FROM AUTHOR]

Published

2022

3. Ultrafast transient absorption spectroelectrochemistry: femtosecond to nanosecond excited-state relaxation dynamics of the individual components of an anthraquinone redox couple.

Author

Goia, Sofia, Turner, Matthew A. P., Woolley, Jack M., Horbury, Michael D., Borrill, Alexandra J., Tully, Joshua J., Cobb, Samuel J., Staniforth, Michael, Hine, Nicholas D. M., Burriss, Adam, Macpherson, Julie V., Robinson, Ben R., and Stavros, Vasilios G.

Published

2022

4. Lifting the lid on the potentiostat: a beginner's guide to understanding electrochemical circuitry and practical operation.

Author

Colburn, Alex W., Levey, Katherine J., O'Hare, Danny, and Macpherson, Julie V.

Abstract

Students who undertake practical electrochemistry experiments for the first time will come face to face with the potentiostat. To many this is simply a box containing electronics which enables a potential to be applied between a working and reference electrode, and a current to flow between the working and counter electrode, both of which are outputted to the experimentalist. Given the broad generality of electrochemistry across many disciplines it is these days very common for students entering the field to have a minimal background in electronics. This article serves as an introductory tutorial to those with no formalized training in this area. The reader is introduced to the operational amplifier, which is at the heart of the different potentiostatic electronic circuits and its role in enabling a potential to be applied and a current to be measured is explained. Voltage follower op-amp circuits are also highlighted, given their importance in measuring voltages accurately. We also discuss digital to analogue and analogue to digital conversion, the processes by which the electrochemical cell receives input signals and outputs data and data filtering. By reading the article, it is intended the reader will also gain a greater confidence in problem solving issues that arise with electrochemical cells, for example electrical noise, uncompensated resistance, reaching compliance voltage, signal digitisation and data interpretation. We also include trouble shooting tables that build on the information presented and can be used when undertaking practical electrochemistry. [ABSTRACT FROM AUTHOR]

Published

2021

5. Controlling palladium morphology in electrodeposition from nanoparticles to dendrites via the use of mixed solvents.

Author

Hussein, Haytham E. M., Amari, Houari, Breeze, Ben G., Beanland, Richard, and Macpherson, Julie V.

Published

2020

6. Addressing the practicalities of anodic stripping voltammetry for heavy metal detection: a tutorial review.

Author

Borrill, Alexandra J., Reily, Nicole E., and Macpherson, Julie V.

Subjects

METAL detectors, MERCURY electrodes, VOLTAMMETRY, HEAVY metals, ENVIRONMENTAL sampling, METAL ions, ANALYSIS of heavy metals, MERCURY

Abstract

Anodic Stripping Voltammetry (ASV) has the capability to detect heavy metals at sub ppb-level with portable and cheap instrumentation making it ideal for in the field (at the source) analysis, however, commercial activity is surprisingly limited. The more commonly used liquid mercury electrodes are now obsolete due to toxicity concerns, and replacements are all based around solid electrodes, which come with their own challenges. This tutorial review aims to discuss the experimental practicalities of ASV, providing a clear overview of the issues for consideration, which can serve as a guide for anyone wanting to undertake analytical ASV. Choice of electrode material (with or without subsequent modification) and solution composition (pH, electrolyte, buffer) are important parameters, as well as an understanding of pH dependent metal speciation and possible intermetallic effects. Measurements made on model solutions often differ from those made on environmental samples with the latter containing organic matter, biological and inorganic species, which themselves can adsorb metal ions. Consideration should also be given to the method of solution collection and the sample container utilised. ASV can be a powerful tool to an analytical chemist, however optimisation for the application of interest is essential, which this review aims to help guide. [ABSTRACT FROM AUTHOR]

Published

2019

7. Switching on palladium catalyst electrochemical removal from a palladium acetate–acetonitrile system via trace water addition.

Author

Hussein, Haytham E. M., Ray, Andrew D., and Macpherson, Julie V.

Subjects

PALLADIUM catalysts, PALLADIUM, SUZUKI reaction, WATER, ELECTROPLATING, ACETONITRILE

Abstract

Palladium acetate (Pd-acetate) is a common catalyst used in a wide array of organic synthetic reactions in non-aqueous solvents. Due to its high cost and associated toxicity/contamination issues in reaction mixtures, Pd removal and recovery is essential. Here we explore the use of electrodeposition as a means to remove Pd from an acetonitrile (MeCN) based Suzuki cross coupling reaction solution, by plating metallic Pd onto the surface of an electrode (boron doped diamond). We show the importance of adding tolerable volumes of water to the reaction mixture in order to facilitate the electrodeposition process. In MeCN, strong coordination bonds exist between the Pd cation and acetate groups and electrodeposition is not possible. By adding water in controlled quantities we show using spectroscopic, electrochemical and microscopic techniques that acetate ligands are released from Pd co-ordination and first replaced by MeCN molecules, enabling electrodeposition. As the water content increases, the MeCN co-ordinating molecules are replaced by water, due to the favourable water–MeCN interactions overcoming those of Pd cation–MeCN, also promoting electrodeposition. We show that sufficient perturbation of the Pd-acetate structure to enable electrodeposition is possible in MeCN solutions containing as little as 5% water (v/v). We demonstrate 99.4% removal of Pd, as metallic Pd plated onto the electrode surface, from a Suzuki reaction solution, using electrochemical methods. [ABSTRACT FROM AUTHOR]

Published

2019

8. Conductive diamond: synthesis, properties, and electrochemical applications.

Author

Yang, Nianjun, Yu, Siyu, Macpherson, Julie V., Einaga, Yasuaki, Zhao, Hongying, Zhao, Guohua, Swain, Greg M., and Jiang, Xin

Subjects

ELECTROCHEMICAL analysis, DIAMONDS, BIOCOMPATIBILITY, DOPING agents (Chemistry), ELECTRODES

Abstract

Conductive diamond possesses unique features as compared to other solid electrodes, such as a wide electrochemical potential window, a low and stable background current, relatively rapid rates of electron-transfer for soluble redox systems without conventional pretreatment, long-term responses, stability, biocompatibility, and a rich surface chemistry. Conductive diamond microcrystalline and nanocrystalline films, structures and particles have been prepared using a variety of approaches. Given these highly desirable attributes, conductive diamond has found extensive use as an enabling electrode across a variety of fields encompassing chemical and biochemical sensing, environmental degradation, electrosynthesis, electrocatalysis, and energy storage and conversion. This review provides an overview of the fundamental properties and highlights recent progress and achievements in the growth of boron-doped (metal-like) and nitrogen and phosphorus-doped (semi-conducting) diamond and hydrogen-terminated undoped diamond electrodes. Applications in electroanalysis, environmental degradation, electrosynthesis electrocatalysis, and electrochemical energy storage are also discussed. Diamond electrochemical devices utilizing micro-scale, ultramicro-scale, and nano-scale electrodes as well as their counterpart arrays are viewed. The challenges and future research directions of conductive diamond are discussed and outlined. This review will be important and informative for chemists, biochemists, physicists, materials scientists, and engineers engaged in the use of these novel forms of carbon. [ABSTRACT FROM AUTHOR]

Published

2019

9. Comparison of fast electron transfer kinetics at platinum, gold, glassy carbon and diamond electrodes using Fourier-transformed AC voltammetry and scanning electrochemical microscopy.

Author

Tan, Sze-yin, Lazenby, Robert A., Bano, Kiran, Zhang, Jie, Bond, Alan M., Macpherson, Julie V., and Unwin, Patrick R.

Abstract

Heterogeneous electron transfer (ET) processes at electrode/electrolyte interfaces are of fundamental and applied importance and are extensively studied by a range of electrochemical techniques, all of which have various attributes but also limitations. The present study focuses on the one-electron oxidation of tetrathiafulvalene (TTF) and reduction of tetracyanoquinodimethane (TCNQ) in acetonitrile solution by two powerful electrochemical techniques: Fourier-transformed large amplitude alternating current voltammetry (FTACV); and scanning electrochemical microscopy (SECM), both of which are supported by detailed theoretical models. At conventional Pt, Au and glassy carbon (GC) electrode materials, the apparent (overall) charge transfer kinetic values determined by FTACV give standard ET rate constants, k0FTACV, that are fast and close to the reversible limit. They are in good agreement with highly localised k0SECM measurements determined by SECM under conditions of high mass transport rates. In contrast, the impact of both the complex heterogeneous surface of polycrystalline boron doped diamond (pBDD) and degenerate p-type doping results in a range of k0SECM values across the electrode surface compared to the overall k0FTACV measured for both processes studied. Moreover, the reduced availability of charge carriers at the electrode surface, at each energy state, compared to a metal, which decreases as the potential becomes more negative, results in lower k0 values at pBDD than Pt, Au and GC. The measurement technique also has an influence: SECM measurements are made at much higher local current density than FTACV, and for TCNQ/TCNQṖ−, which has the more negative formal potential, limited charge carrier availability results in k0FTACV ＞ k0SECM, with unusual apparent charge transfer coefficients and voltammetric waveshapes from SECM. These data thus highlight the importance of understanding the influence of the measurement technique and further demonstrate how ET kinetics at pBDD differ from conventional electrodes, in this case for processes in an organic solvent, which has received much less attention compared to aqueous systems for studies with pBDD. [ABSTRACT FROM AUTHOR]

Published

2017

10. Quantitative analysis of trace palladium contamination in solution using electrochemical X-ray fluorescence (EC-XRF).

Author

Ayres, Zoë J., Newton, Mark E., and Macpherson, Julie V.

Subjects

X-ray fluorescence, PALLADIUM, ELECTRODES, ELECTROCHEMISTRY, ACETAMINOPHEN

Abstract

The application of electrochemical X-ray fluorescence (EC-XRF), for the detection of palladium (Pd) contamination in a range of solutions containing electrochemically active compounds, present in excess and relevant to the pharmaceutical and food industries, is reported. In EC-XRF, EC is used to electrochemically pre-concentrate metal on an electrode under forced convection conditions, whilst XRF is employed to spectroscopically quantify the amount of metal deposited, which quantitatively correlates with the original metal concentration in solution. Boron doped diamond is used as the electrode due to its very wide cathodic window and the fact that B and C are non-interfering elements for XRF analysis. The effect of several parameters on the Pd XRF signal intensity are explored including: deposition potential (Edep), deposition time (tdep) and Pd2+ concentration, [Pd2+]. Under high deposition potentials (Edep = −1.5 V), the Pd XRF peak intensity varies linearly with both tdep and [Pd2+]. Quantification of [Pd2+] is demonstrated in the presence of excess acetaminophen (ACM), l-ascorbic acid, caffeine and riboflavin. We show the same Pd XRF signal intensity (for [Pd2+] = 1.1 μM and tdep = 325 s) is observed, i.e. same amount of Pd is deposited on the electrode surface, irrespective of whether these redox active molecules are present or absent. For tdep = 900 s we report a limit of detection for [Pd2+] of 3.6 ppb (34 nM). Even lower LODs are possible by increasing tdep or by optimising the X-ray source specifically for Pd. The work presented for Pd detection in the presence of ACM, achieves the required detection sensitivity stipulated by international pharmacopeia guidelines. [ABSTRACT FROM AUTHOR]

Published

2016

11. Manipulation and measurement of pH sensitive metal–ligand binding using electrochemical proton generation and metal detection.

Author

Read, Tania L., Joseph, Maxim B., and Macpherson, Julie V.

Subjects

LIGAND binding (Biochemistry), METALS, METAL detectors, ELECTRODES, ACID-base equilibrium

Abstract

Generator-detector electrodes can be used to both perturb and monitor pH dependant metal–ligand binding equilibria, in situ. In particular, protons generated at the generator locally influence the speciation of metal (Cu2+) in the presence of ligand (triethylenetetraamine), with the detector employed to monitor, in real time, free metal (Cu2+) concentrations. [ABSTRACT FROM AUTHOR]

Published

2016

12. Controlled functionalisation of single-walled carbon nanotube network electrodes for the enhanced voltammetric detection of dopamine.

Author

E, Sharel P., Miller, Thomas S., Macpherson, Julie V., and Unwin, Patrick R.

Abstract

Voltammetric studies of dopamine (DA) oxidation on pristine and acid-treated single-walled carbon nanotube (SWNT) network electrodes were undertaken in order to investigate both the effect of network density and acid treatment times on the voltammetric characteristics for DA oxidation and the susceptibility of the electrodes to fouling. Through careful control of catalysed chemical vapour deposition growth parameters, multiply interconnected and randomly oriented SWNT networks of two significantly different densities were grown (high density, HD, coverage >10 μm length of SWNT per μm−2 and low density, LD, coverage = 5 (±1) μmSWNTμm−2). Acid treatment was performed to provide materials with different electrochemical properties and SWNT coverage, as determined by field emission-scanning electron microscopy, atomic force microscopy and micro-Raman spectroscopy. A high concentration of DA (100 μM) was deliberately employed to accelerate the fouling phenomenon associated with DA oxidation in order to evaluate the lifetime of the electrodes. HD pristine SWNT networks were found to promote more facile electron transfer (ET) and were less susceptible to blocking, compared to LD pristine SWNT networks. Acid treatment resulted in both a further enhancement of the ET rate and a reduction in susceptibility towards electrode fouling. However, lengthy acid treatment detrimentally affected ET, due to a decrease in network density and significant damage to the SWNT network structure. These studies highlight the subtle interplay between SWNT coverage and degree of acid functionalisation when seeking to achieve the optimal SWNT electrode for the voltammetric detection of DA. [ABSTRACT FROM AUTHOR]

Published

2015

13. Electrochemical electron paramagnetic resonance utilizing loop gap resonators and micro-electrochemical cells.

Author

Tamski, Mika A., Macpherson, Julie V., Unwin, Patrick R., and Newton, Mark E.

Abstract

A miniaturised electrochemical cell design for Electron Paramagnetic Resonance (EPR) studies is reported. The cell incorporates a Loop Gap Resonator (LGR) for EPR investigation of electrochemically generated radicals in aqueous (and other large dielectric loss) samples and achieves accurate potential control for electrochemistry by using micro-wires as working electrodes. The electrochemical behaviour of the cell is analysed with COMSOL finite element models and the EPR sensitivity compared to a commercial TE011 cavity resonator using 4-hydroxy-2,2,6,6-tetramethylpiperidin-1-oxyl (TEMPOL) as a reference. The electrochemical EPR performance is demonstrated using the reduction of methyl viologen as a redox probe in both water and acetonitrile. The data reported herein suggest that sub-micromolar concentrations of radical species can be detected in aqueous samples with accurate potential control, and that subtle solution processes coupled to electron transfer, such as comproportionation reactions, can be studied quantitatively using EPR. [ABSTRACT FROM AUTHOR]

Published

2015

14. A practical guide to using boron doped diamond in electrochemical research.

Author

Macpherson, Julie V.

Abstract

Conducting, boron doped diamond (BDD), in addition to its superior material properties, offers several notable attributes to the electrochemist making it an intriguing material for electrochemical research. These include the widest solvent window of all electrode materials; low background and capacitive currents; reduced fouling compared to other electrodes and; the ability to withstand extreme potentials, corrosive and high temperature/pressure environments. However, BDD is not your typical electrode material, it is a semi-conductor doped degenerately with boron to present semi-metallic characteristics. Input from materials scientists, chemists and physicists has been required to aid understanding of how to work with this material from an electrochemical viewpoint and improve electrode quality. Importantly, depending on how the BDD has been grown and then subsequently treated, prior to electrochemical measurement, the resulting material properties can vary quite significantly from one electrode to the next. This likely explains the variability seen by different researchers working on the same experimental systems. The aim of this “protocols” article is not to provide a state-of-the-art review of diamond electrochemistry, suitable references are provided to the interested reader, but instead serves as a reference point for any researcher wishing to commence work with diamond electrodes and interpret electrochemical data. It provides information on how best to characterise the material properties of the electrode before use and outlines the interplay between boron dopant density, non-diamond-carbon content, grain morphology, surface chemistry and redox couple identity. All should ideally be considered when interpretating electrochemical data arising from the diamond electrode. This will aid the reader in making meaningful comparisons between data obtained by different researchers using different diamond electrodes. The guide also aims to help educate the researcher in choosing which form of BDD is best suited to their research application. [ABSTRACT FROM AUTHOR]

Published

2015

15. Electrochemical "read-write" microscale patterning of boron doped diamond electrodes.

Author

Patten, Hollie V., Hutton, Laura A., Webb, Jennifer R., Newton, Mark E., Unwin, Patrick R., and Macpherson, Julie V.

Subjects

ELECTRODES, BORON, ANALYTICAL chemistry, SEMICONDUCTOR doping profiles, DIAMONDS, SCANNING electrochemical microscopy, MICROFLUIDIC devices

Abstract

Scanning electrochemical cell microscopy is utilised as a read-write pipette-based probe to both electrochemically modify the local surface chemistry of boron doped diamond and ''read'' the resulting modification, at the micron scale. In this specific application, localised electrochemical oxidation results in conversion of the H-terminated surface to O, electrochemically visualised by monitoring the current change for reduction of Ru(NH3)63+. This methodology, in general, provides a platform for read-write analysis of electrodes, opening up new analytical avenues, particularly as the pipette can be viewed as a microfluidic device. [ABSTRACT FROM AUTHOR]

Published

2015

16. Selection, characterisation and mapping of complex electrochemical processes at individual single-walled carbon nanotubes: the case of serotonin oxidation.

Author

Güell, Aleix G., Dudin, Petr V., Ebejer, Neil, Byers, Joshua C., Macpherson, Julie V., Unwin, Patrick R., and Meadows, Katherine E.

Abstract

The electrochemical (EC) oxidation of the neurotransmitter, serotonin, at individual single-walled carbon nanotubes (SWNTs) is investigated at high resolution using a novel platform that combines flow-aligned SWNTs with atomic force microscopy, Raman microscopy, electronic conductance measurements, individual SWNT electrochemistry and high-resolution scanning electrochemical cell microscopy (SECCM). SECCM has been used to visualise the EC activity along side-wall sections of metallic SWNTs to assess the extent to which side-walls promote the electrochemistry of this complex multi-step process. Uniform and high EC activity is observed that is consistent with significant reaction at the side-wall, rather than electrochemistry being driven by defects alone. By scanning forward and reverse (trace and retrace) over the same region of a SWNT, it is also possible to assess any blocking of EC activity by serotonin oxidation reaction products. At a physiologically relevant concentration (5 μM), there is no detectable blocking of SWNTs, which can be attributed, at least in part, to the high diffusion rate to an individual, isolated SWNT in the SECCM format. At higher serotonin concentration (2 mM), oligomer formation from oxidation products is much more significant and major blocking of the EC process is observed from line profiles recorded as the SECCM meniscus moves over an SWNT. The SECCM line profile morphology is shown to be highly diagnostic of whether blocking occurs during EC processes. The studies herein add to a growing body of evidence that various EC processes at SWNTs, from simple outer sphere redox reactions to complex multi-step processes, occur readily at pristine SWNTs. The platform described is of general applicability to various types of nanostructures and nanowires. [ABSTRACT FROM AUTHOR]

Published

2014

17. Laser heated boron doped diamond electrodes: effect of temperature on outer sphere electron transfer processes.

Author

Meng, Lingcong, Iacobini, James G., Joseph, Maxim B., Macpherson, Julie V., and Newton, Mark E.

Abstract

Thermoelectrochemical experiments can reveal significant information about electrochemical processes compared to ambient only measurements. Typical thermoelectrochemistry is performed using resistively heated wires or laser heated electrodes, both of which can suffer drawbacks associated with the electrode material employed. Boron doped diamond (BDD) is ideal for thermoelectrochemical investigations due to its extremely high thermal conductivity and diffusivity, extreme resistance to thermal ablation (can withstand laser power densities, Pd, of GW cm−2 for nanosecond pulses) and excellent electrochemical properties (low background currents and wide potential window). In this paper we describe the use of a pulsed laser technique to heat the rear of a 1 mm diameter conducting BDD disc electrode, which drives electrochemical solution reactions at the front face. Maximum electrode temperatures of 90.0 °C were recorded experimentally and confirmed by finite element modelling (FEM). The effect of laser pulsed heating (maximum 3.8 kW cm−2; 10 ms on and 90 ms off) on the cyclic voltammetric response of two fast (reversible) outer sphere electron transfer redox mediators (Ru(NH3)63+/2+ and IrCl62−/3−) are investigated. In particular, we observe pulsed increases in the current, which increase with increasing Pd. The potential of the peak current is shifted positively for the Ru(NH3)63+/2+ couple (in accordance with a positive temperature coefficient, β, +0.68 mV K−1) and negatively for the IrCl63−/2− couple (β = −0.48 mV K−1). Scanning backwards, in contrast to that observed for a macrodisc electrode in ambient solution, a cathodic peak is again observed for Ru(NH3)63+/2+ and an anodic peak for IrCl63−/2− couple. We attribute this response to the entropy of the redox reaction and the time-dependant change in mass transport due to the induced thermal gradients at the electrode/electrolyte interface. The observed responses are in qualitative agreement with FEM simulations. [ABSTRACT FROM AUTHOR]

Published

2014

18. Investigation of molecular partitioning between non polar oil droplets and aqueous solution using double potential step chronoamperometry.

Author

Newland, Jonathan C., Unwin, Patrick R., and Macpherson, Julie V.

Abstract

Double potential step chronoamperometry (DPSC) is demonstrated as a technique for investigating partitioning between a solute in aqueous solution and non-polar oil droplet(s) immobilised at an electrode. Here a species in aqueous solution which does not partition into the oil phase is converted at the electrode surface into another species which either does not or does partition into the oil drop. The first case is investigated experimentally by considering generation of the ionic redox species, FcTMA2+ from FcTMA+, while the second case is exemplified by studies of Br2 generation from Br−. The case of molecular partitioning at the three phase interface has received little attention hitherto. To maintain oil droplet stability a boron-doped diamond electrode is employed functionalised with Pt nanoparticles to impart electrocatalytic activity on the electrode towards Br2 production. An arrangement is utilised where the droplet(s) sit(s) on (but does not cover) the electrode surface. We show both experimentally and through finite element simulation how the charge–time profile for the generation and collection of electroactive species can be used to obtain information on the extent of partitioning and how this is affected by factors such as the number and size of droplets. Finally, we highlight the suitability of this approach for investigating reactions which take place within the droplet. [ABSTRACT FROM AUTHOR]

Published

2014

19. Electrochemical activation of pristine single walled carbon nanotubes: impact on oxygen reduction and other surface sensitive redox processes.

Author

Miller, Thomas S., Macpherson, Julie V., and Unwin, Patrick R.

Abstract

The effect of systematic anodic pre-treatments of pristine single walled carbon nanotube (SWNT) forests on the electrochemical response towards a variety of redox processes is investigated. An experimental arrangement is adopted whereby a microcapillary containing the solution of interest and a quasi reference-counter electrode is brought into contact with a small portion of the forest to enable measurements on the surface before and after controlled anodic polarisation (AP). AP of the surface is found to both improve the voltammetric response (faster apparent heterogeneous electron transfer kinetics) of surface sensitive redox processes, such as Fe2+/3+, and enhance the electrocatalytic response of the SWNTs towards oxygen reduction; the extent of which can be carefully controlled via the applied anodic potential. AP is expected to remove any trace organic (atmospheric) contaminants that may accumulate on the forest over extended periods as well as allowing the controlled introduction of defects, as confirmed by micro-Raman spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2014

20. Investigation of film formation properties during electrochemical oxidation of serotonin (5-HT) at polycrystalline boron doped diamond.

Author

Patel, Anisha N., Unwin, Patrick R., and Macpherson, Julie V.

Abstract

The change in surface morphology of oxygen-terminated polycrystalline boron doped diamond (pBDD) during electrochemical oxidation of the neurotransmitter serotonin (5-HT), resulting in a corresponding deterioration of the current signal, is investigated for the first time using both high resolution ex situ and in situ microscopy under a range of different electrochemical conditions. In situ electrochemical-atomic force microscopy (EC-AFM) reveals the formation of a granular film over the surface, which grows faster at higher-doped regions of the electrode surface and increases in thickness with repetitive potential cycles. The film properties were investigated using both cyclic voltammetry, with a range of redox species varying in charge, and conducting-AFM. These studies reveal the film to be positively charged and electrically insulating. The extent to which the film forms during 5-HT oxidation could be significantly minimised using different electrochemical procedures, as verified by voltammetry and in situ EC-AFM. Finally, even after extensive film formation, the original current signal could be recovered simply by leaving the electrode at open circuit potential for a short period of time, highlighting the suitability of BDD electrodes for neurotransmitter detection. [ABSTRACT FROM AUTHOR]

Published

2013

21. Visualisation of electrochemical processes at optically transparent carbon nanotube ultramicroelectrodes (OT-CNT-UMEs).

Author

Rutkowska, Agnieszka, Bawazeer, Tahani M., Macpherson, Julie V., and Unwin, Patrick R.

Abstract

Optically transparent ultramicroelectrodes (OT-UMEs) comprising carbon nanotube (CNT) networks on quartz, are introduced and used to monitor quantitatively the interfacial concentration of tris(2,2′-bipyridine)ruthenium(ii) during cyclic voltammetry. The OT-CNT-UMEs combine the attractive properties of small-scale electrodes, e.g., high diffusion rates and good signal-to-noise, with the ability to probe electrochemical processes optically, from the rear of the electrode. This enables optical measurements of the solution, close to the electrode surface, without significant interference from absorption or scattering processes. [ABSTRACT FROM AUTHOR]

Published

2011

22. Trace voltammetric detection of serotonin at carbon electrodes: comparison of glassy carbon, boron doped diamond and carbon nanotube network electrodes.

Author

GüellBoth authors contributed equally to this work., Aleix G., Meadows, Katherine E., Unwin, Patrick R., and Macpherson, Julie V.

Abstract

The characteristics of three different carbon electrodes, glassy carbon (GC), oxygen-terminated polycrystalline boron-doped diamond (pBDD) and “pristine” carbon nanotube networks (CNTN) as voltammetric sensors for detection of the neurotransmitter serotonin have been investigated. For each electrode, detection sensitivity was determined using cyclic voltammetry (CV), a technique often used to provide information on chemical identity in electrochemical assays. The CNTN electrodes were found to exhibit background current densities ca.two orders of magnitude smaller than the GC electrode and ca.twenty times smaller than pBDD, as a consequence of their “pristine” low capacitance and low surface coverage. This was a major factor in determining serotonin detection limits from CV, of 10 nM for the CNTN electrode, 500 nM for pBDD and 2 μM for GC. The two most sensitive electrodes (CNTN and pBDD) were further investigated in terms of resistance to electrode fouling. CV analysis showed that fouling was less on the pBDD electrode compared to the CNTN and, furthemore, for the case of pBDD could be significantly minimised by careful selection of the CV potential limits, in particular by scanning the electrode potential to suitably cathodic values after oxidation of the serotonin. [ABSTRACT FROM AUTHOR]

Published

2010

23. Electrochemistry at carbon nanotubes: perspective and issues.

Author

Dumitrescu, Ioana, Unwin, Patrick R., and Macpherson, Julie V.

Subjects

ELECTROCHEMISTRY, CARBON nanotubes, ELECTRODES, ELECTROCATALYSIS, NANOPARTICLES, CHARGE exchange, CHEMICAL processes

Abstract

Electrochemistry at carbon nanotubes (CNTs) is a large and growing field, but one in which there is still uncertainty about the fundamental activity of CNTs as electrode materials. On the one hand, there are many reports which focus on the favourable electrochemical properties of CNT electrodes, such as enhanced detection sensitivity, electrocatalytic effects and reduced fouling. On the other hand, other studies suggest that CNTs may be no more electroactive than graphitic powder. Furthermore, it has been proposed that the catalytic nanoparticles from which CNTs are formed may dominate the electrochemical characteristics in some instances. A considerable body of the literature presumes that the CNT sidewall is inert and that edge-plane-graphite-like open ends and defect sites are responsible for the electron transfer activity observed. In contrast, studies of well characterised single-walled nanotube (SWNT) electrodes, either as individual tubes or as two-dimensional networks, suggest sidewall activity. This review highlights how the various discrepancies in CNT electrochemistry may have arisen, by taking a historical view of the field and identifying crucial issues that still need to be solved. When assessing the behaviour of CNT electrodes, it is vitally important that careful consideration is given to the type of CNT used (SWNT or multi-walled), the quality of the material (presence of impurities), the effect of chemical processing steps in the fabrication of electrodes and the experimental arrangements adopted. Understanding these key features is an essential requirement to develop a fundamental understanding of CNT electrochemistry, to allow a wide range of electroanalytical applications, and to move the field forward rationally. As part of this process, high resolution electrochemical and electrical imaging techniques are expected to play a significant role in the future, as well as theoretical developments which examine the fundamentals of electron transfer at different types of CNTs and their characteristic surface sites. [ABSTRACT FROM AUTHOR]

Published

2009

24. New strategies for probing crystal dissolution kinetics at the microscopic level.

Author

Unwin, Patrick R. and Macpherson, Julie V.

Published

1995

25. Boron doped diamond ultramicroelectrodes: a generic platform for sensing single nanoparticle electrocatalytic collisions.

Author

Wakerley, David, Güell, Aleix G., Hutton, Laura A., Miller, Thomas S., Bard, Allen J., and Macpherson, Julie V.

Subjects

BORON, ULTRAMICROELECTRODES, NANOPARTICLES, COLLISIONS (Physics), HYDRAZINE, OXIDATION

Abstract

Boron doped diamond (BDD) disk ultramicroelectrodes have been used to sense single nanoparticle (NP) electrocatalytic collision events. BDD serves as an excellent support electrode due to its electrocatalytic inactivity and low background currents and thus can be used to detect the electroactivity of a wide range of colliding NPs, with high sensitivity. In particular, single NP collisions for hydrazine oxidation at Au and Pt NPs were shown to be markedly different. [ABSTRACT FROM AUTHOR]

Published

2013

26. Enhanced visible photoluminescence in ultrathin poly(3-hexylthiophene) films by incorporation of Au nanoparticles.

Author

Nicholson, Patrick G., Ruiz, Virginia, Macpherson, Julie V., and Unwin, Patrick R.

Published

2005

27. Scanning electrochemical microscopy as a probe of local fluid flow through porous solids.

Author

Macpherson, Julie V., Beeston, Mark A., Unwin, Patrick R., Hughes, Nigel P., and Littlewood, David

Published

1995

28. Imaging local mass-transfer rates within an impinging jet and studies of fast heterogeneous electron-transfer kinetics using the microjet electrode.

Author

Macpherson, Julie V., Beeston, Mark A., and Unwin, Patrick R.

Published

1995

29. Probing the oxidative etching kinetics of metals with the feedback mode of the scanning electrochemical microscope.

Author

Macpherson, Julie V., Slevin, Christopher J., and Unwin, Patrick. R.

Published

1996

30. Faraday communications. A new approach to the study of dissolution kinetics.

Author

Macpherson, Julie V. and Unwin, Patrick R.

Published

1993

31. Ultrafast transient absorption spectroelectrochemistry: femtosecond to nanosecond excited-state relaxation dynamics of the individual components of an anthraquinone redox couple.

Author

Goia S, Turner MAP, Woolley JM, Horbury MD, Borrill AJ, Tully JJ, Cobb SJ, Staniforth M, Hine NDM, Burriss A, Macpherson JV, Robinson BR, and Stavros VG

Abstract

Many photoactivated processes involve a change in oxidation state during the reaction pathway and formation of highly reactive photoactivated species. Isolating these reactive species and studying their early-stage femtosecond to nanosecond (fs-ns) photodynamics can be challenging. Here we introduce a combined ultrafast transient absorption-spectroelectrochemistry (TA-SEC) approach using freestanding boron doped diamond (BDD) mesh electrodes, which also extends the time domain of conventional spectrochemical measurements. The BDD electrodes offer a wide solvent window, low background currents, and a tuneable mesh size which minimises light scattering from the electrode itself. Importantly, reactive intermediates are generated electrochemically, via oxidation/reduction of the starting stable species, enabling their dynamic interrogation using ultrafast TA-SEC, through which the early stages of the photoinduced relaxation mechanisms are elucidated. As a model system, we investigate the ultrafast spectroscopy of both anthraquinone-2-sulfonate (AQS) and its less stable counterpart, anthrahydroquinone-2-sulfonate (AH 2 QS). This is achieved by generating AH 2 QS in situ from AQS via electrochemical means, whilst simultaneously probing the associated early-stage photoinduced dynamical processes. Using this approach we unravel the relaxation mechanisms occurring in the first 2.5 ns, following absorption of ultraviolet radiation; for AQS as an extension to previous studies, and for the first time for AH 2 QS. AQS relaxation occurs via formation of triplet states, with some of these states interacting with the buffered solution to form a transient species within approximately 600 ps. In contrast, all AH 2 QS undergoes excited-state single proton transfer with the buffered solution, resulting in formation of ground state AHQS - within approximately 150 ps., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2021

32. Intrinsic electrochemical activity of single walled carbon nanotube-Nafion assemblies.

Author

Snowden ME, Edwards MA, Rudd NC, Macpherson JV, and Unwin PR

Subjects

Electrochemical Techniques, Fluorocarbon Polymers chemistry, Nanotubes, Carbon chemistry

Abstract

The intrinsic electrochemical properties and activity of single walled carbon nanotube (SWNT) network electrodes modified by a drop-cast Nafion film have been determined using the one electron oxidation of ferrocene trimethyl ammonium (FcTMA(+)) as a model redox probe in the Nafion film. Facilitated by the very low transport coefficient of FcTMA(+) in Nafion (apparent diffusion coefficient of 1.8 × 10(-10) cm(2) s(-1)), SWNTs in the 2-D network behave as individual elements, at short (practical) times, each with their own characteristic diffusion, independent of neighbouring sites, and the response is diagnostic of the proportion of SWNTs active in the composite. Data are analysed using candidate models for cases where: (i) electron transfer events only occur at discrete sites along the sidewall (with a defect density typical of chemical vapour deposition SWNTs); (ii) all of the SWNTs in a network are active. The first case predicts currents that are much smaller than seen experimentally, indicating that significant portions of SWNTs are active in the SWNT-Nafion composite. However, the predictions for a fully active SWNT result in higher currents than seen experimentally, indicating that a fraction of SWNTs are not connected and/or that not all SWNTs are wetted completely by the Nafion film to provide full access of the redox mediator to the SWNT surface.

Published

2013

33. Electrochemistry at carbon nanotube forests: sidewalls and closed ends allow fast electron transfer.

Author

Miller TS, Ebejer N, Güell AG, Macpherson JV, and Unwin PR

Abstract

The electrochemical properties of the closed ends and sidewalls of pristine carbon nanotube forests are investigated directly using a nanopipet electrochemical cell. Both are shown to promote fast electron transfer, without any activation or processing of the carbon nanotube material required, in contrast to the current model in the literature.

Published

2012

34. Electro-oxidation of hydrazine at gold nanoparticle functionalised single walled carbon nanotube network ultramicroelectrodes.

Author

Dudin PV, Unwin PR, and Macpherson JV

Abstract

Networks of pristine single walled carbon nanotubes (SWNTs) grown by catalysed chemical vapour deposition (cCVD) on an insulating surface and arranged in an ultramicroelectrode (UME) format are insensitive to the electro-oxidation of hydrazine (HZ) in aqueous solution, indicating a negligible metallic nanoparticle content. Sensitisation of the network towards HZ oxidation is promoted by the deliberate and controlled electrodeposition of "naked" gold (Au) nanoparticles (NPs). By controlling the deposition conditions (potential, time) it is possible to control the size and spacing of the Au NPs on the underlying SWNT network. Two different cases are considered: Au NPs at a number density of 250 ± 13 NPs μm(-2) and height 24 nm ± 5 (effective surface coverage, θ = 92%) and (ii) Au NPs of number density ~ 22 ± 3 NPs μm(-2) and height 43 nm ± 8 nm (θ = 35%). For both morphologies the HZ oxidation half-wave potential (E(1/2)) is shifted significantly negative by ca. 200 mV, compared to a gold disc UME of the same geometric area, indicating significantly more facile electron transfer kinetics. E(1/2) for HZ oxidation for the higher density Au NP-SWNT structure is shifted slightly more negative (by ~25 mV) than E(1/2) for the lower density Au NP electrode. This is attributed to the lower flux of HZ at NPs in the higher number density arrangement (smaller kinetic demand). Importantly, using this approach, the calculated HZ oxidation current density sensitivities for the Au NP-SWNT electrodes reported here are higher than for many other metal NP functionalised carbon nanotube electrodes.

Published

2011

35. Trace voltammetric detection of serotonin at carbon electrodes: comparison of glassy carbon, boron doped diamond and carbon nanotube network electrodes.

Author

Güell AG, Meadows KE, Unwin PR, and Macpherson JV

Subjects

Catalysis, Electric Conductivity, Electrodes, Limit of Detection, Oxidation-Reduction, Serotonin chemistry, Volatilization, Water chemistry, Boron chemistry, Diamond chemistry, Electrochemistry methods, Glass chemistry, Nanotubes, Carbon chemistry, Serotonin analysis

Abstract

The characteristics of three different carbon electrodes, glassy carbon (GC), oxygen-terminated polycrystalline boron-doped diamond (pBDD) and "pristine" carbon nanotube networks (CNTN) as voltammetric sensors for detection of the neurotransmitter serotonin have been investigated. For each electrode, detection sensitivity was determined using cyclic voltammetry (CV), a technique often used to provide information on chemical identity in electrochemical assays. The CNTN electrodes were found to exhibit background current densities ca. two orders of magnitude smaller than the GC electrode and ca. twenty times smaller than pBDD, as a consequence of their "pristine" low capacitance and low surface coverage. This was a major factor in determining serotonin detection limits from CV, of 10 nM for the CNTN electrode, 500 nM for pBDD and 2 microM for GC. The two most sensitive electrodes (CNTN and pBDD) were further investigated in terms of resistance to electrode fouling. CV analysis showed that fouling was less on the pBDD electrode compared to the CNTN and, furthermore, for the case of pBDD could be significantly minimised by careful selection of the CV potential limits, in particular by scanning the electrode potential to suitably cathodic values after oxidation of the serotonin.

Published

2010

36. Synthesis of azide/alkyne-terminal polymers and application for surface functionalisation through a [2 + 3] Huisgen cycloaddition process, "click chemistry".

Author

Chen G, Tao L, Mantovani G, Ladmiral V, Burt DP, Macpherson JV, and Haddleton DM

Abstract

Living radical polymerization of methyl methacrylate (MMA) and a fluorescent comonomer with 2-bromo-2-methylpropionic acid 3-azidopropyl ester and 2-bromo-2-methylhept-6-yn-3-one as initiators has been successfully employed for the synthesis of fluorescently tagged azide and alkyne terminated PMMA with close to that predicted, PDI < 1.20, and good first order kinetics as expected for a living polymerisation. Cotton and organic resin surfaces have been functionalised with alkyne groups using a condensation with 4-chlorocarbonylbutyric acid prop-2-ynyl ester. The surfaces have been further modified using a Huisgen [2 + 3] cycloaddition ("click") reaction of polymeric and small molecule azides. Different functional azides, mono azido-PEG and a new fluorescent hostasol derivative have been prepared and tested as model substrates for cotton surface modification. FTIR, tensiometry, FE-SEM and confocal spectroscopy have been used to characterize the modified surfaces. Tensiometry shows an increase in the hydrophobicity of the surface; verified by FE-SEM which shows a change in surface morphology. The use of the fluorescence label allows fluorescent and confocal microscopy to demonstrate the surface reactions. This approach is shown to be very general allowing soft and hard surfaces with different geometries to be modified. In particular it is an excellent method to alter the nature of organic resins allowing the incorporation of many different functionalities.

Published

2007

37. Effect of composition on the conductivity and morphology of poly(3-hexylthiophene)/gold nanoparticle composite Langmuir-Schaeffer films.

Author

Nicholson PG, Ruiz V, Macpherson JV, and Unwin PR

Subjects

Electrochemistry methods, Electrodes, Microscopy, Atomic Force, Microscopy, Electron, Scanning, Nanostructures chemistry, Nanotechnology methods, Ultraviolet Rays, Gold chemistry, Nanoparticles chemistry, Sulfhydryl Compounds chemistry, Thiophenes chemistry

Abstract

Ultrathin Langmuir-Schaeffer (LS) films were fabricated from blends of regioregular poly(3-hexylthiophene) (P3HT) and highly monodispersed dodecanethiolate-capped gold nanoparticles (Au NPs) mixed in varying weight ratios. The morphology of the ultrathin films was investigated by UV-visible absorption spectroscopy, atomic force microscopy (AFM) and field-emission scanning electron microscopy (FE-SEM). The results of the structural investigations were correlated with the lateral conductivity of the films, with P3HT in its unintentionally doped state, probed by scanning electrochemical microscopy (SECM), which proved to be a very sensitive technique. Control over the P3HT/Au NP ratio led to remarkable changes in the morphology and lateral conductivity of the films. Inclusion of Au NPs into P3HT was found to influence the ordering of P3HT, which ultimately determined the macroscopic charge transport characteristics of the films. Composite films with ca. 33% by weight of Au NPs were found to be the most ordered and exhibited the highest conductivity, substantially higher than P3HT alone. To provide insight into the film formation process, LS composite films comprising equal quantities of P3HT and Au NPs (by weight) were transferred at several surface pressures and investigated by SECM, AFM and FE-SEM.

Published

2006

38. Electron beam lithographically-defined scanning electrochemical-atomic force microscopy probes: fabrication method and application to high resolution imaging on heterogeneously active surfaces.

Author

Dobson PS, Weaver JM, Burt DP, Holder MN, Wilson NR, Unwin PR, and Macpherson JV

Subjects

Ceramics, Electrochemistry methods, Image Enhancement, Insulator Elements, Surface Properties, Microscopy, Atomic Force methods, Silicon Compounds chemistry

Abstract

This paper describes in detail the use of electron beam lithography (EBL) to successfully batch microfabricate combined scanning electrochemical-atomic force microscopy (SECM-AFM) probes. At present, the process produces sixty probes at a time, on a 1/4 of a three-inch wafer. Using EBL, gold triangular-shaped electrodes can be defined at the tip apex, with plasma enhanced chemical vapor deposited silicon nitride serving as an effective insulating layer, at a thickness of 75 nm. The key features of the fabrication technique and the critical steps are discussed. The capability of these probes for SECM-AFM imaging in both tapping and constant distance mode is illustrated with dual topographical-electrochemical scans over an array of closely-spaced 1 microm diameter Pt disc electrodes, held at a suitable potential to generate an electroactive species at a transport-limited rate. As highlighted herein, understanding diffusion to heterogeneous electrode surfaces, including array electrodes, is currently topical and we present preliminary data highlighting the use of SECM-AFM as a valuable tool for the investigation of diffusion and reactivity at high spatial resolution.

Published

2006

39. Luminescent nanobeads: attachment of surface reactive Eu(III) complexes to gold nanoparticles.

Author

Lewis DJ, Day TM, MacPherson JV, and Pikramenou Z

Subjects

Microscopy, Electron, Transmission, Molecular Structure, Europium chemistry, Gold chemistry, Luminescence, Nanoparticles chemistry

Abstract

Gold nanoparticles were used as a scaffold to assemble multiple tailor-made europium(III) complexes yielding water-soluble gold nanoparticles that display red, Eu(III), luminescence.

Published

2006

40. Scanning electrochemical microscopy as a probe of Ag+ binding kinetics at Langmuir phospholipid monolayers.

Author

Burt DP, Cervera J, Mandler D, Macpherson JV, Manzanares JA, and Unwin PR

Subjects

Adsorption, Binding Sites, Cations, Electrochemistry, Kinetics, Phosphatidic Acids chemistry, Phosphatidic Acids metabolism, Phospholipids metabolism, Surface Properties, Time Factors, Microscopy, Scanning Probe methods, Phospholipids chemistry, Silver chemistry

Abstract

A new method has been developed for measuring local adsorption rates of metal ions at interfaces based on scanning electrochemical microscopy (SECM). The technique is illustrated with the example of Ag+ binding at Langmuir phospholipid monolayers formed at the water/air interface. Specifically, an inverted 25 microm diameter silver disc ultramicroelectrode (UME) was positioned in the subphase of a Langmuir trough, close to a dipalmitoyl phosphatidic acid (DPPA) monolayer, and used to generate Ag+ via Ag electro-oxidation. The method involved measuring the transient current-time response at the UME when the electrode was switched to a potential to electrogenerate Ag+. Since the Ag+/Ag couple is reversible, the response is highly sensitive to local mass transfer of Ag+ away from the electrode, which, in turn, is governed by the interaction of Ag+ with the monolayer. The methodology has been used to determine the influence of surface pressure on the adsorption of Ag+ ions at a phospholipid (dipalmitoyl phosphatidic acid) Langmuir monolayer. It is shown that the capacity for metal ion adsorption at the monolayer increased as the density of surface adsorption sites increased (by increasing the surface pressure). A model for mass transport and adsorption in this geometry has been developed to explain and characterise the adsorption process.

Published

2005

41. Fabrication and electrocatalytic properties of polyaniline/Pt nanoparticle composites.

Author

O'Mullane AP, Dale SE, Macpherson JV, and Unwin PR

Abstract

Polyaniline (PANI)/Pt nanoparticle composites can be prepared by the spontaneous redox reaction of K2PtCl4 with PANI, to yield thin films that show electrocatalytic properties in both acidic and neutral aqueous media.

Published

2004