Towards indoor lighting-powered thin-film, fl | EurekAlert!

2022-06-09 06:56:00 By : Ms. coco Pan

Ritsumeikan University researchers demonstrate improved photovoltaic cell performance using a piezoelectric semiconductor

image: Ritsumeikan University researchers demonstrate improved photovoltaic cell performance using a piezoelectric semiconductor view more 

In 2010, a research team led by Professor Zhong Lin Wang at Georgia Institute of Technology, USA, showed that the use of piezoelectric materials (materials that generate electrical energy on applying mechanical strain) could improve the performance of optoelectronic devices – devices that convert light into electricity (e.g. solar cells) or electricity into light (e.g. light-emitting diodes or LEDs).

Using piezoelectric zinc oxide (ZnO) nanowires, the research team was able to tune the bandgap of ZnO and optimize the electrical properties of the nanowires by simultaneously bending the wire and exposing it to a laser source. Their results paved the way for developing new kinds of self-powered flexible electronic devices whose properties can be controlled by piezoelectric and photoelectric effects.

Against this backdrop, in a new study, researchers from Ritsumeikan University, Japan, have now developed a novel thin-film flexible piezoelectric-photovoltaic device that can generate electricity simply from indoor lighting produced by LEDs and compact fluorescent lamps. The device, which is paper-thin and just 10 mm long, was made by depositing thin films of ZnMgO, an electron-rich n-type piezoelectric material, and selenium (Se), a low cost, electron-deficient p-type material that can efficiently absorb indoor room light, on a flexible PET plastic film. By using ZnMgO as the piezoelectric material, the researchers managed to fabricate the photovoltaic device using an entirely dry process, avoiding the need for chemical solutions.

“In this work, the piezo-phototronic effect was applied to ZnMgO/Se heterojunction photovoltaic devices for the first time,” says Professor Taizo Kobayashi, the corresponding author of the study. This paper was made available online on 18 May 2022 and published in Volume 99 of the journal Nano Energy in August 2022.

The two semiconducting materials when joined together created a p-n junction at the interface whose electronic band structure could be controlled by bending the device.

“When compressive strain is applied on the ZnMgO layer, a negatively polarized ZnMgO region is formed near the Se layer. This polarization decreases the conduction band offset at the interface of ZnMgO and Se layers”, explains Prof. Kobayashi.

By optimizing the bandgap at the p-n junction, the researchers were able to overcome one of the main causes of poor performance in solar cells: charge recombination. In this process, the electrons excited by light recombine with the “holes” (vacancies left behind by electrons), resulting in a loss of charge carriers that would otherwise produce electricity. By inducing strain-induced polarization in the ZnMgO layer, the researchers managed to increase the open-circuit voltage (a measure of the useful charge carriers generated) from 0.59 V to 0.75 V.

However, bending the device also caused cracks to form in the electrode layer, resulting in a drop in the current density and its capability to convert light into electricity. Nevertheless, the researchers are confident that the problem can be solved using more robust materials, such as graphene. “In the future, we will develop alternative transparent conducting electrodes that would be more durable against strain,” says Prof. Kobayashi. “For now, the fact that our paper was accepted by a journal as prestigious as Nano Energy provides a great opportunity for us to promote our research.”

With their dedicated efforts, piezophototronics could become the technology for future thin-film solar cells.

DOI: https://doi.org/10.1016/j.nanoen.2022.107385

Ritsumeikan University is one of the most prestigious private universities in Japan. Its main campus is in Kyoto, where inspiring settings await researchers. With an unwavering objective to generate social symbiotic values and emergent talents, it aims to emerge as a next-generation research university. It will enhance researcher potential by providing support best suited to the needs of young and leading researchers, according to their career stage. Ritsumeikan University also endeavors to build a global research network as a “knowledge node” and disseminate achievements internationally, thereby contributing to the resolution of social/humanistic issues through interdisciplinary research and social implementation.

Website: http://en.ritsumei.ac.jp/

About Professor Taizo Kobayashi from Ritsumeikan University, Japan

Taizo Kobayashi is currently a Professor at the Department of Mechanical Engineering at Ritsumeikan Univsersity, Japan, where he joined in 2017. He received his BS, MS, and PhD degree from Ritsumeikan University in 1999, 2001, and 2009, respectively. His research focuses on advanced functional thin films for device applications. He has co-authored 34 papers so far.

He can be reached at: tkt07004@fc.ritsumei.ac.jp

This work was also supported in part by Program for Application of the Grants-in-Aid for Scientific Research (KAKENHI acquisition promotion) in Ritsumeikan University.

Impact of piezo-phototronic effect on ZnMgO/Se heterojunction photovoltaic devices

The authors declare no competing interests.

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Kazuki Kurajo Ritsumeikan University kurajo@st.ritsumei.ac.jp Office: 81-758-138-300

Professor Taizo Kobayashi Department of Mechanical Engineering, Ritsumeikan University tkt07004@fc.ritsumei.ac.jp

Copyright © 2022 by the American Association for the Advancement of Science (AAAS)

Copyright © 2022 by the American Association for the Advancement of Science (AAAS)