Design Optimization of Solar Energy Harvesting Using Perovskite Solar Cell for Electric Vehicles Using Finite Element Method

Q3 Engineering

SAE Technical Papers Pub Date : 2023-11-10 DOI:10.4271/2023-28-0095

Geetha P

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Abstract

Excellent charge-carrier mobilities and life time of perovskite materials enables it with exceptional light absorption capacity. This provides improved device potential and performance with low-cost commercially feasible technology. The challenges towards handling the perovskite cells are its strength and its environmentally compatible property. Resolving these issues leads perovskite-based technology to hold an innovative potential for quick terawatt-scale solar power distribution. In this line, Organic Photovoltaic is a fast developing PV technology with improved the cell efficiency and life time performance. As organic Photovoltaic cell is available in mulit-colours and can be used to build transparent devices, it finds its application in building-integrated Organic Photovoltaic fair. Optimization of device physics, charge-transport methods, charge-separation procedures, and interfacial effects, would enable the development of stable, more effective device architectures. In this direction, multi-physics simulation software based on the Finite Element Method (FEM) is used to determine the electrical performance of the device. It is constructed on materials with enhanced energy-level orientation, spectrum responsiveness, and carrier transport properties, leading to the design of more effective, reliable device architectures. In this work, hybrid perovskite semiconductor based 2D Organic Photovoltaic cell is developed using finite element method that can be applied on the roof of the electric vehicles for photo energy generation.

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基于有限元法的电动汽车钙钛矿太阳能电池太阳能收集优化设计

<div class="section abstract"><div class="htmlview段落">钙钛矿材料优良的载流子迁移率和寿命使其具有优异的光吸收能力。这提供了提高设备的潜力和性能与低成本的商业可行的技术。处理钙钛矿电池的挑战在于它的强度和环境相容性。解决这些问题使得基于钙钛矿的技术在快速太瓦级太阳能发电方面具有创新潜力。在这方面，有机光伏是一种快速发展的光伏技术，提高了电池效率和寿命性能。由于有机光伏电池有多种颜色可供选择，并可用于建造透明装置，因此在建筑集成有机光伏博览会中得到了应用。器件物理、电荷传输方法、电荷分离程序和界面效应的优化，将使稳定、更有效的器件体系结构的发展成为可能。在此方向上，采用基于有限元法(FEM)的多物理场仿真软件来确定器件的电气性能。它构建在具有增强的能级取向、频谱响应性和载流子输运特性的材料上，从而设计出更有效、更可靠的器件架构。在这项工作中，采用有限元方法开发了基于混合钙钛矿半导体的二维有机光伏电池，该电池可应用于电动汽车车顶进行光能发电。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

SAE Technical Papers Engineering-Industrial and Manufacturing Engineering

CiteScore

1.00

自引率

0.00%

发文量

1487

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