Observations and Theories of Quantum Effects in Proton Transfer Electrode Processes

16 August 2019, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Quantum tunneling effects play an important role in a variety of chemical reactions considerably affecting the reaction rates via opening the classically-forbidden paths and emerging as highly efficient or selective processes. However, in the case of electrochemical reactions, quantum tunneling effects are less investigated due to complicated nature of chemical interactions at the electrified interfaces. In this review, we summarize the experimental/theoretical concept of electrochemical quantum proton tunneling (EQPT), which is a key element in microscopic electrode processes. First, we review the experimental observations of EQPT, and next, we discuss possible theoretical pictures of the process. This review shows that a combination of a wide spectrum of scientific efforts is required to understand microscopic mechanism of EQPT including development of the precise electrochemistry-oriented experimental techniques and methodologies, formulation of the appropriate theoretical models for specific systems and performance of the advanced computational simulations.

Keywords

Multi-electron/-proton transfer electrode process
Quantum Tunneling
Microscopic mechanism
Theory for physical electrochemistry
Surface electrochemistry

Comments

Comments are not moderated before they are posted, but they can be removed by the site moderators if they are found to be in contravention of our Commenting Policy [opens in a new tab] - please read this policy before you post. Comments should be used for scholarly discussion of the content in question. You can find more information about how to use the commenting feature here [opens in a new tab] .
This site is protected by reCAPTCHA and the Google Privacy Policy [opens in a new tab] and Terms of Service [opens in a new tab] apply.