Humboldt-Universität zu Berlin - Faculty of Mathematics and Natural Sciences - Department of Physics

Humboldt-Universität zu Berlin | Faculty of Mathematics and Natural Sciences | Department of Physics | Colloquium | Colloquia | Department Colloquium: Prof. Hiromichi Ohta, Ph.D. (RIES, Hokkaido University)

Department Colloquium: Prof. Hiromichi Ohta, Ph.D. (RIES, Hokkaido University)

lecture: Solid-state electrochemical thermal transistors
  • When Jun 11, 2024 from 03:00 to 05:00
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Prof. Hiromichi Ohta, Ph.D. (RIES, Hokkaido University) will talk about:

Solid-state electrochemical thermal transistors

Abstract

Thermal transistors are devices that can electrically switch “heat flow” on and off, like a semiconductor transistor that switches “electric current” on and off. We can reuse waste heat exhausted to the environment using devices composed of thermal transistors such as thermal shutters and thermal displays. Although several thermal transistors have been demonstrated thus far, the use of liquid electrolytes (or ionic liquids or ion gels) may limit the application from the viewpoint of reliability or liquid leakage. Very recently, we demonstrated a solid-state thermal transistor that can electrochemically control the heat flow with an on-to-off ratio of the thermal conductivity (κ) of ~4 without using any liquid.[1] The thermal transistor is a multilayer film composed of an upper electrode (Pt), strontium cobaltite (SrCoOx), solid electrolyte (YSZ), and bottom electrode (Pt). An electrochemical redox treatment at 280 °C in air repeatedly modulates the crystal structure and κ of the SrCoOx layer. The fully oxidized perovskite-structured SrCoO3 layer shows a high κ ~3.8 W m−1 K−1, whereas the fully reduced defect perovskite-structured SrCoO2 layer shows a low κ ~0.95 W m−1 K−1. We believe that all-solid-state electrochemical thermal transistors have the potential to become next-generation devices for future thermal management technology, and we are currently working on improving their characteristics.

[1] Q. Yang, H. Ohta et al., Adv. Funct. Mater. 33, 2214939 (2023).

 

The Colloquium will be held in "hybrid" format, i.e., you can join the talk in the lecture hall or via zoom.
Zoom Link:
https://hu-berlin.zoom.us/j/64567336962?pwd=QjhyMW5SbFVBZWVNRWJrTFBFN2Rtdz09
Meeting-ID: 645 6733 6962
Passwort: 607723