Kathryn Gillow : Publications

Journal papers

• [1]

  Theoretical and experimental investigation of surface−confined two−center metalloproteins by large−amplitude fourier transformed ac voltammetry

  Fraser A. Armstrong Chong−Yong Lee Gareth P. Stevenson Alison Parkin Maxie M. Roessler Ruth E. Baker Kathryn Gillow David J. Gavaghan and Alan M. Bond

  In Journal of Electroanalytical Chemistry. 2010.

  Details about Theoretical and experimental investigation of surface−confined two−center metalloproteins by large−amplitude fourier transformed ac voltammetry | BibTeX data for Theoretical and experimental investigation of surface−confined two−center metalloproteins by large−amplitude fourier transformed ac voltammetry

• [2]

  Designer based Fourier transformed voltammetry: A multi−frequency‚ variable amplitude‚ sinusoidal waveform

  YJ Tan GP Stevenson RE Baker D Elton K Gillow J Zhang AM Bond and DJ Gavaghan

  In Journal of Electroanalytical Chemistry. Vol. 634. No. 1. Pages 11−21. 2009.

  Details about Designer based Fourier transformed voltammetry: A multi−frequency‚ variable amplitude‚ sinusoidal waveform | BibTeX data for Designer based Fourier transformed voltammetry: A multi−frequency‚ variable amplitude‚ sinusoidal waveform

• [3]

  Adaptive Finite Element Methods in Electrochemistry

  D.J. Gavaghan‚ K. Gillow and E. Süli

  In Langmuir. Vol. 22. No. 25. Pages 10666–10682. 2006.

  Details about Adaptive Finite Element Methods in Electrochemistry | BibTeX data for Adaptive Finite Element Methods in Electrochemistry

• [4]

  Finite Element Solution of A Membrane Covered Electrode Problem

  K. Gillow‚ D.J. Gavaghan and E. Süli

  In Journal of Electroanalytical Chemistry. Vol. 587. No. 1. Pages 18–24. 2006.

  Details about Finite Element Solution of A Membrane Covered Electrode Problem | BibTeX data for Finite Element Solution of A Membrane Covered Electrode Problem

• [5]

  Computation of Currents at Microelectrodes using hp−DGFEM

  K. Gillow‚ D.J. Gavaghan and E. Süli

  In Journal of Electroanalytical Chemistry. Vol. 587. No. 1. Pages 1–17. 2006.

  Details about Computation of Currents at Microelectrodes using hp−DGFEM | BibTeX data for Computation of Currents at Microelectrodes using hp−DGFEM

• [6]

  Fourier Transformed Large Amplitude Square Wave Voltammetry as an Alternative to Impedance Spectroscopy: Evaluation of Resistance‚ Capacitance and Electrode Kinetic Effects via a Heuristic Approach

  A.A. Sher‚ A.M. Bond‚ D.J. Gavaghan‚ K. Gillow‚ N.W. Duffy‚ S.X. Guo and J. Zhang

  In Electroanalysis. Vol. 17. No. 15–16. Pages 1450–1462. 2005.

  Details about Fourier Transformed Large Amplitude Square Wave Voltammetry as an Alternative to Impedance Spectroscopy: Evaluation of Resistance‚ Capacitance and Electrode Kinetic Effects via a Heuristic Approach | BibTeX data for Fourier Transformed Large Amplitude Square Wave Voltammetry as an Alternative to Impedance Spectroscopy: Evaluation of Resistance‚ Capacitance and Electrode Kinetic Effects via a Heuristic Approach

• [7]

  Resistance‚ Capacitance and Electrode Kinetic Effects in Fourier Transformed Large Amplitude Sinusoidal Voltammetry: The Emergence of Powerful and Intuitively Obvious Tools for Recognition of Patterns of Behaviour

  A.A. Sher‚ A.M. Bond‚ D.J. Gavaghan‚ K. Harriman‚ S.W. Feldberg‚ N.W. Duffy‚ S.X. Guo and J. Zhang

  In Analytical Chemistry. Vol. 76. No. 21. Pages 6214−6228. 2004.

  Details about Resistance‚ Capacitance and Electrode Kinetic Effects in Fourier Transformed Large Amplitude Sinusoidal Voltammetry: The Emergence of Powerful and Intuitively Obvious Tools for Recognition of Patterns of Behaviour | BibTeX data for Resistance‚ Capacitance and Electrode Kinetic Effects in Fourier Transformed Large Amplitude Sinusoidal Voltammetry: The Emergence of Powerful and Intuitively Obvious Tools for Recognition of Patterns of Behaviour

• [8]

  Simulation of Linear Sweep Voltammetry Using an Adaptive Finite Element Algorithm

  K. Harriman‚ D.J. Gavaghan and E. Süli

  In Journal of Electroanalytical Chemistry. Vol. 573. No. 1. Pages 169–174. 2004.

  Details about Simulation of Linear Sweep Voltammetry Using an Adaptive Finite Element Algorithm | BibTeX data for Simulation of Linear Sweep Voltammetry Using an Adaptive Finite Element Algorithm

• [9]

  Time dependent EC'‚ ECE and EC2E mechanisms at microdisc electrodes: simulations using adaptive finite element methods

  K. Harriman‚ D.J. Gavaghan and and E. Süli

  In Journal of Electroanalytical Chemistry. Vol. 569. No. 1. Pages 35–46. 2004.

  Details about Time dependent EC'‚ ECE and EC2E mechanisms at microdisc electrodes: simulations using adaptive finite element methods | BibTeX data for Time dependent EC'‚ ECE and EC2E mechanisms at microdisc electrodes: simulations using adaptive finite element methods

• [10]

  Adaptive Finite Element Simulation of Chronoamperometry at Microdisc Electrodes

  K. Harriman‚ D.J. Gavaghan and E. Süli

  In Electrochemistry Communications. Vol. 5. No. 7. Pages 519–529. 2003.

  Details about Adaptive Finite Element Simulation of Chronoamperometry at Microdisc Electrodes | BibTeX data for Adaptive Finite Element Simulation of Chronoamperometry at Microdisc Electrodes

• [11]

  Finite Element Simulation of Electrochemically Reversible‚ Quasi−Reversible and Irreversible Linear Sweep Voltammetry at the Wall Tube Electrode

  O.V. Klymenko‚ D.J. Gavaghan‚ K. Harriman and R.G. Compton

  In Journal of Electroanalytical Chemistry. Vol. 531. No. 1. Pages 25–31. 2002.

  Details about Finite Element Simulation of Electrochemically Reversible‚ Quasi−Reversible and Irreversible Linear Sweep Voltammetry at the Wall Tube Electrode | BibTeX data for Finite Element Simulation of Electrochemically Reversible‚ Quasi−Reversible and Irreversible Linear Sweep Voltammetry at the Wall Tube Electrode

• [12]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: ECE and EC2E Mechanisms at Channel Microband Electrodes

  K. Harriman‚ D.J. Gavaghan‚ P. Houston‚ D. Kay and E. Süli

  In Electrochemistry Communications. Vol. 2. No. 8. Pages 576–585. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: ECE and EC2E Mechanisms at Channel Microband Electrodes | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: ECE and EC2E Mechanisms at Channel Microband Electrodes

• [13]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: An E Reaction at a Channel Microband Electrode

  K. Harriman‚ D.J. Gavaghan‚ P. Houston and E. Süli

  In Electrochemistry Communications. Vol. 2. No. 8. Pages 567–575. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: An E Reaction at a Channel Microband Electrode | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: An E Reaction at a Channel Microband Electrode

• [14]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: First Order EC' Mechanism at Inlaid and Recessed Discs

  K. Harriman‚ D.J. Gavaghan‚ P. Houston and E. Süli

  In Electrochemistry Communications. Vol. 2. No. 3. Pages 163−170. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: First Order EC' Mechanism at Inlaid and Recessed Discs | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: First Order EC' Mechanism at Inlaid and Recessed Discs

• [15]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Theory

  K. Harriman‚ D.J. Gavaghan‚ P. Houston and E. Süli

  In Electrochemistry Communications. Vol. 2. No. 3. Pages 157–162. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Theory | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Theory

• [16]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Application to a Simple Model Problem

  K. Harriman‚ D.J. Gavaghan‚ P. Houston and E. Süli

  In Electrochemistry Communications. Vol. 2. No. 3. Pages 150–156. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Application to a Simple Model Problem | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to Guaranteed Accuracy: Application to a Simple Model Problem

Conference papers

• [1]

  hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form

  K. Harriman‚ P. Houston‚ B. Senior and E. Süli

  In C.−W. Shu‚ T. Tang and S.−Y. Cheng, editors, Recent Advances in Scientific Computing and Partial Differential Equations. 2003.

  Contemporary Mathematics Vol. 330‚ pp. 89–119‚ AMS

  Details about hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form | BibTeX data for hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form

Technical reports

• [1]

  Finite Element Simulation of a Membrane Covered Electrode Problem

  K. Harriman‚ D.J. Gavaghan and E. Süli

  No. NA04/21. Oxford University Computing Laboratory. 2004.

  Details about Finite Element Simulation of a Membrane Covered Electrode Problem | BibTeX data for Finite Element Simulation of a Membrane Covered Electrode Problem | Link to Finite Element Simulation of a Membrane Covered Electrode Problem

• [2]

  Application of hpDGFEM to Mechanisms at Channel Microband Electrodes

  K. Harriman‚ D.J. Gavaghan and E. Süli

  No. NA04/20. Oxford University Computing Laboratory. 2004.

  Details about Application of hpDGFEM to Mechanisms at Channel Microband Electrodes | BibTeX data for Application of hpDGFEM to Mechanisms at Channel Microband Electrodes | Link to Application of hpDGFEM to Mechanisms at Channel Microband Electrodes

• [3]

  Approximation of Linear Functionals Using an hp−Adaptive Discontinuous Galerkin Finite Element Method

  K. Harriman‚ D.J. Gavaghan and E. Süli

  No. NA04/19. Oxford University Computing Laboratory. 2004.

  Details about Approximation of Linear Functionals Using an hp−Adaptive Discontinuous Galerkin Finite Element Method | BibTeX data for Approximation of Linear Functionals Using an hp−Adaptive Discontinuous Galerkin Finite Element Method | Link to Approximation of Linear Functionals Using an hp−Adaptive Discontinuous Galerkin Finite Element Method

• [4]

  The Importance of Adjoint Consistency in the Approximation of Linear Functionals Using the Discontinuous Galerkin Finite Element Method

  K. Harriman‚ D.J. Gavaghan and E. Süli

  No. NA04/18. Oxford University Computing Laboratory. 2004.

  Details about The Importance of Adjoint Consistency in the Approximation of Linear Functionals Using the Discontinuous Galerkin Finite Element Method | BibTeX data for The Importance of Adjoint Consistency in the Approximation of Linear Functionals Using the Discontinuous Galerkin Finite Element Method | Link to The Importance of Adjoint Consistency in the Approximation of Linear Functionals Using the Discontinuous Galerkin Finite Element Method

• [5]

  hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form

  K. Harriman‚ P. Houston‚ W. Senior and E. Süli

  No. NA02/21. Oxford University Computing Laboratory. 2002.

  Details about hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form | BibTeX data for hp−Version Discontinuous Galerkin Methods with Interior Penalty for Partial Differential Equations with Nonnegative Characteristic Form

• [6]

  Adaptive Finite Element Simulation of Currents at Microelectrodes to a Guaranteed Accuracy. Application to Channel Microband Electrodes

  K. Harriman‚ D.J. Gavaghan‚ P. Houston‚ D. Kay and E. Süli

  No. NA00/09. Oxford University Computing Laboratory. 2000.

  Details about Adaptive Finite Element Simulation of Currents at Microelectrodes to a Guaranteed Accuracy. Application to Channel Microband Electrodes | BibTeX data for Adaptive Finite Element Simulation of Currents at Microelectrodes to a Guaranteed Accuracy. Application to Channel Microband Electrodes

• [7]

  Adaptive Finite Element Simulation of Steady State Currents at Microdisc Electrodes to a Guaranteed Accuracy

  K. Harriman‚ D.J. Gavaghan‚ P. Houston and E. Süli

  No. NA99/19. Oxford University Computing Laboratory. 1999.

  Details about Adaptive Finite Element Simulation of Steady State Currents at Microdisc Electrodes to a Guaranteed Accuracy | BibTeX data for Adaptive Finite Element Simulation of Steady State Currents at Microdisc Electrodes to a Guaranteed Accuracy