High-efficiency InAs/GaAs quantum dot solar cells by MOCVD

K. Tanabe, D. Guimard, D. Bordel, R. Morihara, M. Nishioka, Y. Arakawa
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引用次数: 3

Abstract

Quantum dot solar cells can potentially realize ultrahigh efficiencies in single p-n junction structures utilizing intermediate-level energy bands. However, so far most fabricated quantum dot solar cells have suffered from severe reduction of open-circuit voltage by incorporation of quantum dots resulting in significantly lower efficiencies than those without quantum dot. Here we fabricate a high-efficiency InAs/GaAs quantum dot solar cell. Our cell contains five layers of high-density (4 × 1010 cm-2 per layer) self-assembled InAs quantum dots grown by metalorganic chemical vapor deposition suppressing open-circuit-voltage degradation. We develop a dual-layer anti-reflection coating of optimum thicknesses. The resulting cell exhibits efficiencies of 18.7% under AM1.5G, 1 sun and 19.4% for 2 suns, the highest reported thus far, for any kind of quantum dot cell. Our high-efficiency demonstration in a cell grown by MOCVD is a strong encouragement towards the commercialization of quantum dot solar cells.
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MOCVD制备的高效InAs/GaAs量子点太阳能电池
量子点太阳能电池可以利用中能级能带实现单p-n结结构的超高效率。然而,到目前为止,大多数制造的量子点太阳能电池由于加入量子点而导致开路电压严重降低,导致效率明显低于未加入量子点的太阳能电池。本文制备了一种高效的InAs/GaAs量子点太阳能电池。我们的电池包含五层高密度(每层4 × 1010 cm-2)自组装的InAs量子点,通过金属有机化学气相沉积生长,抑制开路电压退化。我们开发了一种最佳厚度的双层增透涂层。该电池在AM1.5G、1次太阳照射下的效率为18.7%,在2次太阳照射下的效率为19.4%,是迄今为止报道的任何量子点电池的最高效率。我们在MOCVD生长的电池中的高效演示是对量子点太阳能电池商业化的有力鼓励。
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