Effects of Alkali and Oxidation Treatments on Efficiency and Stability of CdS/CIGS Solar Cells

Curtis Walkons, T. Friedlmeier, S. Paetel, W. Hempel, M. Nardone, E. Barnard, K. Kweon, V. Lordi, S. Bansal
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Abstract

Three types of CIGS devices with varying treatments of RbF post-deposition treatment (PDT) and sodium are subjected to accelerated stress test (AST) conditions at elevated temperature (65 °C), voltage bias (short- vs open-circuit), and illumination (AM1.5 vs dark). RbF treatment with reduced CdS thickness shows an improvement in Voc and efficiency in this sample series, and also results in high FF and doping ~ 1016cm−3. Cells with reduced sodium show a decrease in Voc and infrared QE results suggest a higher optical minimum bandgap. Heat and light soaking experiments at 50, 65, and 75 °C, open and short-circuit junction bias under AM1.5G illumination suggest stabilization of CIGS solar cells with addition of Na and RbF. SCAPS-1D simulations suggest reduction in thermally ionized defect density in ordered vacancy compound (OVC) and changes in conduction band offset with RbF post-deposition treatment. Further, simulations show an increase in shallow acceptor and donor density after open-circuit and short-circuit AST respectively. Preliminary light soaking results for oxidized CIGS with and without Na are also discussed.
碱和氧化处理对CdS/CIGS太阳能电池效率和稳定性的影响
在高温(65°C)、电压偏置(短路vs开路)和光照(AM1.5 vs暗)条件下,采用不同的RbF后沉积处理(PDT)和钠处理的三种CIGS器件进行了加速应力测试(AST)。减小CdS厚度的RbF处理在该样品系列中显示出Voc和效率的改善,并且还获得了高FF和掺杂~ 1016cm−3。钠减少的电池显示Voc降低,红外QE结果表明光学最小带隙更高。在50,65和75°C下,在AM1.5G照明下进行的热和光浸泡实验表明,添加Na和RbF可以稳定CIGS太阳能电池。SCAPS-1D模拟表明,沉积后RbF处理降低了有序空位化合物(OVC)的热电离缺陷密度,改变了导带偏移量。此外,模拟结果表明,在开路和短路AST后,浅层受体和供体密度分别增加。讨论了含钠和不含钠氧化CIGS的初步光浸泡结果。
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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