P型硅衬底异质结太阳电池的优化设计

汪骏康; 徐静平

半导体光电, 2012, 33 (6): 799, 网络出版: 2012-12-31

P型硅衬底异质结太阳电池的优化设计

Design Optimization of Heterojunction Solar Cells on p-type Silicon Substrates

论文大纲

汪骏康 ^*徐静平

作者单位

华中科技大学电子科学与技术系, 武汉 430074

异质结太阳电池窗口层本征层背场 heterojunction solar cells window layer intrinsic layer back surface field

摘要

采用Afors-het软件模拟分析了结构为TCO/a-Si∶H(n)/a-Si∶H(i)/c-Si(p)/a-Si∶H(p+)/Ag的p型硅衬底异质结太阳电池的性能, 研究了各层厚度、带隙、掺杂浓度以及界面态密度等结构参数和物理参数对电池性能的影响。通过模拟优化, 结合理论分析和实际工艺, 得到合适的各结构参数取值。采用厚度薄且掺杂高的窗口层, 嵌入本征层以钝化异质结界面缺陷, 合理利用背场对于少子的背反作用, 获得了较佳的太阳电池综合性能: 开路电压Voc为678.9mV、短路电流密度Jsc为38.33mA/cm2、填充因子FF为84.05%、转换效率η为21.87%。

Abstract

The performance of TCO/a-Si∶H(n)/a-Si∶H(i)/c-Si(p)/a-Si∶H(p+)/Ag heterojunction solar cells on p-type silicon substrates was simulated by Afors-het software. Optimal structural parameters of thickness, band gap, doping concentration and interface states density were obtained by the results of software optimization and theoretical analysis. The results indicate that well-performed heterojunction solar cells can be designed by using thin and high doping window layer, passivating the defect states of heterojunction interface with intrinsic layer, and making full use of the mirror effect of back surface field. The optimum performance parameters are Voc=678.9mV, Jsc=38.33mA/cm2, FF=84.05%, η=21.87%.

参考文献

[1] 胡志华,廖显伯,曾湘波,等. 纳米硅(nc-Si∶H)/晶体硅(c-Si)异质结太阳电池的数值模拟分析[J]. 物理学报,2003,52(1):217-224.

[2] Zhao L,Zhou C L. Design optimization of bifacial HIT solar cells on p-type silicon substrates by simulation[J]. Solar Energy Materials & Solar Cells, 2008,92(6):673-681.

[3] Fujiwara H,Kondo M. Effects of a-Si∶H layer thickness on the performance of aSi∶H/cSi heterojuntion solar cells[J]. J. Appl. Phys.,2007,101:054516.

[4] Datta A,Rahmouni M, Nath M,et al.Insights gained from computer modeling of heterojunction with instrinsic thin layer "HIT" solar cells[J].Solar Energy Materials & Solar Cells,2010,94:1457-1462.

[5] Chatterjee P.Photovoltaic performance of a-Si∶H homojunction p-i-n solar cells A computer simulation study[J]. J. Appl. Phys.,1994,76(2):1.

[6] Jensen N,Hausner R M, Bergmann R B, et al. Optimization and characterization of amorphous/crystalline silicon heterojunction solar cells[J].Prog.Photovolt.Res.Appl.,2002,10(1):1-13.

[7] Dao V A,Heo J, Choi H,et al. Simulation and study of the influence of the buffer intrinsic layer back-surface field densities of interface defects, resistivity of p-type silicon substrate and transparent conductive oxide on heterojunction with intrinsic thin-layer(HIT) solar cell[J].Solar Energy,2010,84:777-783.

[8] Datta A,Damon-Lacoste J, Nath M,et al. Dominant role of interface in sloar cells with N-a-Si∶H/P-cSi heterojuntion with intrinsic thin layer[J]. Materials Science and Engineering B,2009,159/160:10-13.

[9] 赵雷,周春兰,李海玲,等. a-Si(n)/c-Si(p)异质结太阳电池薄膜硅背场的模拟优化[J].物理学报,2008,57(5):3212-3217.

汪骏康, 徐静平. P型硅衬底异质结太阳电池的优化设计[J]. 半导体光电, 2012, 33(6): 799. WANG Junkang, XU Jingping. Design Optimization of Heterojunction Solar Cells on p-type Silicon Substrates[J]. Semiconductor Optoelectronics, 2012, 33(6): 799.

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