A capacitance mediated positive differential resistance oscillator model for electrochemical systems involving a surface layer

Carla Zensen; Konrad Schönleber; Felix Kemeth; Katharina Krischer

doi:10.1021/jp505418x

A capacitance mediated positive differential resistance oscillator model for electrochemical systems involving a surface layer

Carla Zensen, Konrad Schönleber, Felix Kemeth, Katharina Krischer

Associate Professorship of Technical Physics

Technical University of Munich

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

We present a novel mechanism for potentiostatic current oscillations in systems involving the electrochemical formation and chemical dissolution of a surface layer on the electrode. The essential variables of the model are the capacitance of and the potential drop across the passive layer. Thus, they are both of electrical nature. We discuss the feedback loops destabilizing the stationary states and corroborate that the oscillations occur with an entirely positive faradaic impedance. Furthermore, it is demonstrated that the oscillations develop around a current plateau in a CV and that the model predicts superharmonic resonances in admittance spectra taken at a stable stationary state with oscillatory transients.

Original language	English
Pages (from-to)	24407-24414
Number of pages	8
Journal	Journal of Physical Chemistry C
Volume	118
Issue number	42
DOIs	https://doi.org/10.1021/jp505418x
State	Published - 23 Oct 2014

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abstract = "We present a novel mechanism for potentiostatic current oscillations in systems involving the electrochemical formation and chemical dissolution of a surface layer on the electrode. The essential variables of the model are the capacitance of and the potential drop across the passive layer. Thus, they are both of electrical nature. We discuss the feedback loops destabilizing the stationary states and corroborate that the oscillations occur with an entirely positive faradaic impedance. Furthermore, it is demonstrated that the oscillations develop around a current plateau in a CV and that the model predicts superharmonic resonances in admittance spectra taken at a stable stationary state with oscillatory transients.",

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AU - Zensen, Carla

AU - Schönleber, Konrad

AU - Kemeth, Felix

AU - Krischer, Katharina

PY - 2014/10/23

Y1 - 2014/10/23

N2 - We present a novel mechanism for potentiostatic current oscillations in systems involving the electrochemical formation and chemical dissolution of a surface layer on the electrode. The essential variables of the model are the capacitance of and the potential drop across the passive layer. Thus, they are both of electrical nature. We discuss the feedback loops destabilizing the stationary states and corroborate that the oscillations occur with an entirely positive faradaic impedance. Furthermore, it is demonstrated that the oscillations develop around a current plateau in a CV and that the model predicts superharmonic resonances in admittance spectra taken at a stable stationary state with oscillatory transients.

AB - We present a novel mechanism for potentiostatic current oscillations in systems involving the electrochemical formation and chemical dissolution of a surface layer on the electrode. The essential variables of the model are the capacitance of and the potential drop across the passive layer. Thus, they are both of electrical nature. We discuss the feedback loops destabilizing the stationary states and corroborate that the oscillations occur with an entirely positive faradaic impedance. Furthermore, it is demonstrated that the oscillations develop around a current plateau in a CV and that the model predicts superharmonic resonances in admittance spectra taken at a stable stationary state with oscillatory transients.

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A capacitance mediated positive differential resistance oscillator model for electrochemical systems involving a surface layer

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