C. Bailey, M. Lumb, D. Forbes, M. Yakes, M. González, S. Hubbard, R. Hoheisel, L. Hirst, J. Tischler, I. Vurgaftman, J. Meyer, R. Walters
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引用次数: 4
摘要
近年来,利用量子阱和量子点实现太阳能转换的带隙工程技术已经得到了令人兴奋的结果。本文介绍了一种完全晶格匹配的量子阱/势垒系统,作为这种类型器件的一种有吸引力的新可能性。进行了光伏表征,并报道了相关的太阳能电池参数。将16层5nm InGaAs qw / 10nm InAlGaAs势垒嵌入1.0 eV InAlGaAs太阳电池的i区,并与1.0 eV InAlGaAs对照太阳电池的结果进行了比较。与InAlGaAs控制装置相比,QW电池中的One-sun Jsc提高了5.3%,而开路电压则比控制装置降低了153 mV。外部量子效率测量显示,从QW吸收区获得1.6 mA/cm2增益。
Improved bandgap-voltage offset in InGaAs/InAlGaAs quantum well solar cells
In recent years, the implementation of bandgap engineering techniques for solar energy conversion has been demonstrated with exciting results, using both quantum wells (QWs) and quantum dots. Here, the exploitation of a fully lattice-matched QW / barrier system is introduced as an attractive new possibility for this type of device. Photovoltaic characterization is performed and relevant solar cell parameters are reported. For these devices, sixteen layers of 5 nm InGaAs QWs / 10 nm InAlGaAs barriers were embedded into the i-region of a 1.0 eV InAlGaAs solar cell, and the results compared to a 1.0 eV InAlGaAs control solar cell. One-sun Jsc is enhanced in the QW cell by 5.3% compared to that of the InAlGaAs control device, while the open circuit voltage is reduced by 153 mV compared to the control. External quantum efficiency measurements reveal a 1.6 mA/cm2 gain from the QW absorption region.
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