铁电氧化物中电子-空穴的分离以实现高效光伏响应。

Electron-hole separation in ferroelectric oxides for efficient photovoltaic responses.

机构信息

Division of Advanced Materials Science, Pohang University of Science and Technology, 37673 Pohang, Republic of Korea.

Department of Materials Science and Engineering, Pohang University of Science and Technology, 37673 Pohang, Republic of Korea.

出版信息

Proc Natl Acad Sci U S A. 2018 Jun 26;115(26):6566-6571. doi: 10.1073/pnas.1721503115. Epub 2018 Jun 11.

DOI:10.1073/pnas.1721503115

PMID:29891684

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6042087/

Abstract

Despite their potential to exceed the theoretical Shockley-Queisser limit, ferroelectric photovoltaics (FPVs) have performed inefficiently due to their extremely low photocurrents. Incorporating BiFeCrO (BFCO) as the light absorber in FPVs has recently led to impressively high and record photocurrents [Nechache R, et al. (2015) 9:61-67], which has revived the FPV field. However, our understanding of this remarkable phenomenon is far from satisfactory. Here, we use first-principles calculations to determine that such excellent performance mainly lies in the efficient separation of electron-hole () pairs. We show that photoexcited electrons and holes in BFCO are spatially separated on the Fe and Cr sites, respectively. This separation is much more pronounced in disordered BFCO phases, which adequately explains the observed exceptional PV responses. We further establish a design strategy to discover next-generation FPV materials. By exploring 44 additional Bi-based double-perovskite oxides, we suggest five active-layer materials that offer a combination of strong separations and visible-light absorptions for FPV applications. Our work indicates that charge separation is the most important issue to be addressed for FPVs to compete with conventional devices.

摘要

尽管铁电光伏（FPV）具有超越理论上肖克利-奎塞尔极限的潜力，但由于其极低的光电流，其性能仍不理想。最近，将 BiFeCrO（BFCO）作为 FPV 的光吸收剂，导致了令人印象深刻的高光电流[Nechache R，等人（2015）9:61-67]，这使得 FPV 领域重新焕发活力。然而，我们对这一显著现象的理解还远远不够。在这里，我们使用第一性原理计算来确定，这种优异的性能主要在于电子-空穴（e-h）对的有效分离。我们表明，BFCO 中的光激发电子和空穴分别在 Fe 和 Cr 位上实现空间分离。在无序 BFCO 相中，这种分离更为明显，这充分解释了观察到的异常光伏响应。我们进一步建立了一种设计策略来发现下一代 FPV 材料。通过探索另外 44 种 Bi 基双钙钛矿氧化物，我们建议了五种活性层材料，它们在 FPV 应用中具有较强的分离和可见光吸收的组合。我们的工作表明，对于 FPV 来说，要与传统器件竞争，电荷分离是最需要解决的问题。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a8e3/6042087/ad5a8a3ac7f1/pnas.1721503115fig01.jpg

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铁电氧化物中电子-空穴的分离以实现高效光伏响应。

Electron-hole separation in ferroelectric oxides for efficient photovoltaic responses.

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