Design and simulation of MEMS based radioisotope converter with electrostatic capacitive energy conversion mechanism

Haisheng San; Zaijun Cheng; Zhiqiang Deng; Zhiwen Zhao; Yanfei Li; Xuyuan Chen

Design and simulation of MEMS based radioisotope converter with electrostatic capacitive energy conversion mechanism

Haisheng San, Zaijun Cheng, Zhiqiang Deng, Zhiwen Zhao, Yanfei Li, Xuyuan Chen

Published: 01 Jan 2011, Last Modified: 15 May 2025NEMS 2011EveryoneRevisionsBibTeXCC BY-SA 4.0

Abstract: This paper presents the design and simulation of electrostatic capacitive vibration-to-electricity energy conversion system based on radioisotope Ni63 that produces low energy beta particles. The electrostatic capacitive energy conversion utilizes a variable capacitor to convert radioisotope energy into electrical energy by mechanical vibration as transformed intermediate. The MEMS capacitor is designed as a radioisotope actuated parallel-plate spring-mass-damping structure fabricated through the mature silicon-based micromachining processes. Numerical simulations are performed in order to optimize design parameters targeting a maximum output power. Such a MEMS based energy converter is able to provide an average output power of 0.0812 μW·cm-2 and energy conversion efficiency of about 4% according to the radioisotope activity of 10 mCi·cm-2.

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