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引用次数: 6
摘要
在这里,我们通过系统地实现GGI (Ga/(Ga+ in)比)的深度分级,专门研究了厚度约为500 nm的超薄CIGS (UT -CIGS)薄膜的器件性能。通过调节GGI斜率,开路电压可以显著提高,表明准中性区和背触点的复合减少;在整个吸收光谱的光载流子收集效率显著提高与侵略性的GGI剖面。最终,在厚度为500 nm左右的情况下,通过适当的GGI配置,证明了UT-CIGS器件的功率转换效率超过12%。
Ga/(Ga + In) grading effects on ultra-thin (UT) CIGS solar cell
Here, we specifically address device performance in ultra-thin CIGS (UT UT-CIGS) films with thickness around 500 nm by systematically implementing varying in in-depth grading of the GGI (Ga/(Ga+In)ratio). By adjusting the GGI slope, the open circuit voltage can be significantly improved, indicating a reduction of recombination in the quasiquasi-neutral region and at the back contact; the photocarrier collection efficiency over the whole absorption spectrum enhanced significantly with an aggressive GGI profile. Ultimately, a power conversion efficiency of UT-CIGS device over 12% with thickness around 500 nm by carefully applying a an appropriate GGI profile was demonstrated.
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