中间波段太阳能电池用纤锌矿InGaN/GaN量子点

2019 International Conference on Numerical Simulation of Optoelectronic Devices (NUSOD) Pub Date : 2019-07-01 DOI:10.1109/NUSOD.2019.8806840

Luc Robichaud, J. Krich

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引用次数: 2

摘要

研究了GaN中纤锌矿InGaN量子点在中间波段太阳能电池中的应用。通过详细的平衡计算，在允许的子隙跃迁完全自由的情况下，预测了44%的全局极限功率转换效率。我们考虑圆柱形量子点，使用8波段k.p模型预测能带结构，包括变形势和由诱导晶格应变产生的压电场。在详细的平衡计算中，我们以k.p模型中的能级作为吸收截止点，确定了铟分数和点尺寸的函数可能的最佳器件效率。对于尺寸≈50 Å，铟分数≈0.7的小点，在1个太阳照射下，效率原则上可达42%。

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Wurtzite InGaN/GaN Quantum Dots for Intermediate Band Solar Cells

Wurtzite InGaN quantum dots in GaN are investigated for intermediate band solar cells. A global limiting power conversion efficiency of 44% is predicted through detailed balance calculations with full freedom of allowed subgap transitions. We consider cylindrical quantum dots, predicting band structures using an 8-band k.p model, including deformation potential and piezoelectric fields from induced lattice strain. Taking the energy levels from the k.p model as absorption cutoffs in the detailed balance calculation, we determine the best device efficiency possible as a function of indium fraction and dot size. For small dots, of size ≈ 50 Å and indium fraction ≈ 0.7, efficiencies up to 42% are in principle attainable under 1-sun illumination.

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2019 International Conference on Numerical Simulation of Optoelectronic Devices (NUSOD)

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