光照下纳米片平面横向pn结发电性能的理论估计

IF 0.7 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS
Y. Omura
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引用次数: 0

摘要

本文基于理论模型提出了基于共价半导体的横向p-n结薄膜太阳能器件,并对其在光照下的发电性能进行了研究。所提出的理论模型在仿真中得到了实现和验证。结果表明,虽然Ge薄膜器件在室温下的性能远低于Si薄膜器件,但在250 K以下的温度下,这一顺序明显相反,这是非常有趣的。仿真结果还表明,与Si薄膜器件相比,Ge薄膜器件的载流子生成特性在温度变化方面非常稳定。模拟结果表明,硅薄膜横向p-n结太阳能器件——在透明面板上形成多层堆叠太阳能器件——适用于温度低于300 K的地面现场传感器器件。然而,由于环境温度低于250k,薄ge膜侧向p-n结太阳能器件适用于空间卫星上的现场传感器器件;同样是在透明面板上形成的多层堆叠太阳能装置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Theoretical Estimation of Power Generation Performance of Nano-Sheet Planar Lateral P-N Junction under Illumination
This paper proposes covalent-semiconductor-based lateral p-n junction film solar devices based on a theoretical model, and examines their power generation performance under illumination. The proposed theoretical model is implemented and tested in simulations. The results demonstrate that while Ge film devices have much lower performance at room temperature than Si film devices, this order is significantly reversed at temperatures below 250 K, which is very interesting. The obtained simulation results also reveal that the carrier generation characteristic of Ge film devices is very stable in terms of temperature variation in comparison to Si film devices. The simulation results suggest that thin-Si-film lateral p-n junction solar devices - implemented as multi-stacked solar devices formed on a transparent panel - are applicable to field sensor devices on the ground at temperatures lower than 300 K. However, thin-Ge-film lateral p-n junction solar devices are applicable to field sensor devices on satellites in space because the ambient temperature is lower than 250 K; again as a multi-stacked solar device formed on a transparent panel.
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CiteScore
0.20
自引率
14.30%
发文量
0
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