Planar Transparent Conductive Oxide/Ag Rear Contacts for High Efficiency III-V Photovoltaics

2022 IEEE 49th Photovoltaics Specialists Conference (PVSC) Pub Date : 2022-06-05 DOI:10.1109/pvsc48317.2022.9938673

Christopher Gregory, Sean J. Babcock, R. King

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Abstract

Photon recycling in photovoltaic devices can be attained by using highly reflective back surfaces. Some of the highest reflectance surfaces are composed of a plane of dielectric material deposited on a highly reflective metal such as Ag or Au. Although optically effective, the use of a planar dielectric layer complicates electrical contact to the device, leading to approaches such as point contacts. A simple solution-that may not result in significant optical or resistive losses-is to use a planar transparent conductive oxide (TCO) layer instead of a dielectric layer. This work investigates the viability of a such a contact. It is observed that contact resistivities of the TCO/Ag stack on a highly doped AlGaAs or GaAs contact layer are below 0.1 Ω cm2 for TCO doping concentrations on the order of 1019 cm-3. The contact resistivity can be reduced further by increasing the doping in the semiconductor layer. Internal hemispheric reflectances of the proposed contacts are expected to reach up to 98% at the wavelength of interest, facilitating photon recycling. The performance of this contact structure suggests use in technologies such as photonic power converters and thermophotovoltaics.

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用于高效III-V型光伏的平面透明导电氧化物/银后触点

光电器件中的光子回收可以通过使用高反射背表面来实现。一些反射率最高的表面是由沉积在高反射率金属(如Ag或Au)上的介电材料组成的。虽然光学上有效，但平面介质层的使用使器件的电接触变得复杂，导致诸如点接触的方法。一个简单的解决方案——可能不会导致显著的光学或电阻损失——是使用平面透明导电氧化物(TCO)层代替介电层。这项工作调查了这种接触的可行性。当TCO掺杂浓度为1019 cm-3量级时，高掺杂AlGaAs或GaAs接触层上的TCO/Ag堆叠的接触电阻率低于0.1 Ω cm2。通过增加半导体层中的掺杂，可以进一步降低接触电阻率。所提出的触点的内部半球反射率有望在感兴趣的波长达到98%，促进光子回收。这种接触结构的性能建议在诸如光子功率转换器和热光伏等技术中使用。

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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2022 IEEE 49th Photovoltaics Specialists Conference (PVSC)

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