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引用次数: 11
摘要
我们展示了单晶ZnxCd1−xSySe1−y合金纳米线的化学气相沉积,其在单晶片上具有连续的空间成分分级(x和y从0到1),导致从~ 3.6 eV (ZnS)到~ 1.7eV (CdSe)的可控空间带隙变化。为了利用这种前所未有的光伏应用材料性能,我们分析了几种侧向多结太阳能电池的设计,其中入射的太阳光是光谱分散的,这样每个波长带都入射到具有相应带隙的晶圆片区域上。这种设计具有实现大量结的潜力,从而可以探索许多结的全部潜力,以实现高效的分散聚光光伏。
Spatially composition-graded alloy semiconductor nanowires and wavelength specific lateral-multijunction full-spectrum solar cells
We demonstrate chemical vapor deposition of single crystal ZnxCd1−xSySe1−y alloy nanowires with continuous spatial composition-grading (x and y from 0 to1) across a single wafer, resulting in a controlled spatial bandgap variation from ∼ 3.6 eV (ZnS) to ∼ 1.7eV (CdSe). To take advantage of this unprecedented material capability for photovoltaic applications, we analyzed several designs of lateral multijunction solar cells, where incoming solar light is spectrally dispersed, such that each wavelength band is incident onto a region of the wafer with the corresponding bandgap. Such designs have potential of realizing large numbers of junctions to allow the full potential of many junctions to be explored for high-efficiency dispersive concentration photovoltaics.
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