Progress on III-nitride/silicon hybrid multijunction solar cells

L. Reichertz, I. Gherasoiu, K. Yu, J. Ager, V. M. Kao, W. Walukiewicz
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引用次数: 3

Abstract

We report on the progress towards a high efficiency InGaN/Si tandem hybrid solar cell. The proof of principle has been demonstrated in a 5 × 5 mm III-nitride/Si dual junction solar cell, with p/n GaN junction grown by molecular beam epitaxy (MBE) functioning as the top cell and a standard n-type Si wafer with an Al doped p-type surface functioning as the bottom cell. An open circuit voltage (Voc) of 2.5 V was measured under 1× AM1.5G illumination conditions with additional UV laser illumination of the GaN junction. The quantum efficiency spectra show that both junctions are active and working in series. The 1x sun conversion efficiency of the GaN/Si tandem cell is limited to less than 1% due to the large band gap of GaN not being matched to the solar spectrum. Ongoing work is therefore focused on lowering the bandgap of the top cell to an optimum of about 1.8 eV by increasing the indium content of the top InGaN cell in order to match the current of the Si bottom cell under solar illumination. Very recently, we have achieved PV action in the first InGaN/Si hybrid cells. The remaining challenge lies in maintaining a high quality pn- junction in InGaN as the In fraction has to be increased towards 45%.
氮化硅杂化多结太阳能电池的研究进展
我们报告了高效InGaN/Si串联混合太阳能电池的进展。在5 × 5 mm的iii -氮化物/Si双结太阳能电池中,以分子束外延(MBE)生长的p/n GaN结作为顶电池,以掺杂Al的p型表面的标准n型硅片作为底电池,证明了原理的证明。在1× AM1.5G照明条件下测量了GaN结的开路电压(Voc)为2.5 V。量子效率谱显示两个结都是主动的,并且是串联工作的。GaN/Si串联电池的1倍太阳转换效率由于GaN的大带隙与太阳光谱不匹配而限制在1%以下。因此,正在进行的工作重点是通过增加顶部InGaN电池的铟含量,将顶部电池的带隙降低到约1.8 eV的最佳值,以匹配太阳照射下Si底部电池的电流。最近,我们在第一个InGaN/Si混合电池中实现了PV作用。剩下的挑战在于在InGaN中保持高质量的pn结,因为in分数必须增加到45%。
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