NIMS and Hokkaido University jointly discovered that proton transfer in electrochemical reactions is governed by the quantum tunneling effect (QTE) under the specific conditions. In addition, they made a first ever observation of the transition between the quantum and classical regimes in electrochemical proton transfer by controlling potential.

These results indicated the involvement of QTE in electrochemical proton transfer, a subject of a long-lasting debate, and may accelerate basic research leading to the development of highly efficient electrochemical energy conversion systems based on quantum mechanics.

Many of the state-of-the-art electronic devices and technologies that have realized present modern lives were established based on the fundamental principles of quantum mechanics. Quantum effects in electrochemical reactions in fuel cells and energy devices are, however, not well understood due to the complex movement of electrons and protons driven by electrochemical reaction processes on the surfaces of electrodes.

As the result, application of quantum effects in electrochemical energy conversion is not as successful as the fields of electronics and spintronics, which surface and interfacial phenomena are equally critical in all of these fields. Assuming that electrochemical reactions are closely associated with quantum effects, it may be feasible to design highly efficient energy conversion mechanisms based on these effects: including QTE, and devices that take advantage of such mechanisms.

In this study, the NIMS-led research team focused on oxygen reduction reaction (ORR) mechanisms - the key reaction in fuel cells - using deuterium, an isotope of hydrogen having a different mass. As a result, the team confirmed proton tunneling through activation barriers within a small overpotential range.

Furthermore, the team found that an increase in overpotential leads to electrochemical reaction pathways to change to proton transfer based on the semiclassical theory. Thus, this research team discovered the novel physical processes: the transition between the quantum and classical regimes in electrochemical reactions.

This research shows the involvement of QTE in proton transfer during the basic energy conversion processes. This discovery may facilitate investigations of microscopic mechanisms of electrochemical reactions which are not understood in detail.

It may also stimulate the development of highly efficient electrochemical energy conversion technology with a working principle based on quantum mechanics, capable of operating beyond the classical regime.

Research paper

Related Links
National Institute for Materials Science, Japan
Computer Chip Architecture, Technology and Manufacture
Nano Technology News From SpaceMart.com

Tweet

Thanks for being here; We need your help. The Space Media Network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceMediaNetwork Contributor $5 Billed Once credit card or paypal		SpaceMediaNetwork Monthly Supporter $5 Billed Monthly paypal only

The Quiet light set to move demanding scientific applications to the chip scale
Santa Barbara CA (SPX) Feb 04, 2019
Spectrally pure lasers lie at the heart of precision high-end scientific and commercial applications, thanks to their ability to produce near-perfect single-color light. A laser's capacity to do so is measured in terms of its linewidth, or coherence, which is the ability to emit a constant frequency over a certain period of time before that frequency changes. In practice, researchers go to great lengths to build highly coherent, near-single-frequency lasers for high-end systems such as atomic cloc ... read more