Physical insights into non-fullerene organic photovoltaics

IF 44.8 1区 物理与天体物理 Q1 PHYSICS, APPLIED
Jiayu Wang, Yuan Xie, Kai Chen, Hongbin Wu, Justin M. Hodgkiss, Xiaowei Zhan
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引用次数: 0

Abstract

Boosted by the fast development of non-fullerene acceptors, organic photovoltaics (OPVs) have achieved breakthrough power conversion efficiencies — in excess of 20% and approaching those of state-of-the-art crystalline silicon photovoltaics. New physical properties, unusual phenomena and critical mechanisms have been uncovered in non-fullerene acceptors and related devices, all contributing to deliver advances in OPV technologies. In this Review, we summarize the photophysics and device physics of non-fullerene-acceptor-based OPVs, with emphasis on the comparison between fullerene and non-fullerene acceptors of the physical processes that affect device performance. We discuss the processes of exciton generation, diffusion, transport and separation and charge recombination in OPVs and present recent interpretations of the physics of non-fullerene-acceptor-based OPVs, looking at how driving energy affects exciton separation and how charge recombination affects voltage loss. Compiling these mechanisms — especially those that can overcome the intrinsic limitations imposed by the energy-gap law — we provide a strategy for minimizing voltage loss and discuss future research directions and challenges in the fundamentals and performance of OPVs, including new modes of operation for non-fullerene-acceptor-based OPVs. Non-fullerene acceptors have boosted the development of organic photovoltaics. This Review highlights the photophysics and device physics of non-fullerene organic photovoltaics, including exciton generation, diffusion, transport, separation and charge recombination.

Abstract Image

Abstract Image

非富勒烯有机光伏技术的物理启示
在非富勒烯受体快速发展的推动下,有机光伏技术(OPV)实现了突破性的功率转换效率--超过 20%,接近最先进的晶体硅光伏技术。在非富勒烯受体和相关设备中发现了新的物理性质、不寻常现象和关键机制,这些都有助于实现 OPV 技术的进步。在本综述中,我们总结了基于非富勒烯受体的 OPV 的光物理和器件物理,重点比较了富勒烯和非富勒烯受体中影响器件性能的物理过程。我们讨论了 OPV 中激子产生、扩散、传输和分离以及电荷重组的过程,并介绍了对基于非富勒烯受体的 OPV 物理的最新解释,研究了驱动能量如何影响激子分离以及电荷重组如何影响电压损耗。综合这些机制(尤其是那些能够克服能隙定律所带来的内在限制的机制),我们提出了将电压损耗降至最低的策略,并讨论了未来在 OPV 基本原理和性能方面的研究方向和挑战,包括基于非富勒烯受体的 OPV 的新工作模式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
47.80
自引率
0.50%
发文量
122
期刊介绍: Nature Reviews Physics is an online-only reviews journal, part of the Nature Reviews portfolio of journals. It publishes high-quality technical reference, review, and commentary articles in all areas of fundamental and applied physics. The journal offers a range of content types, including Reviews, Perspectives, Roadmaps, Technical Reviews, Expert Recommendations, Comments, Editorials, Research Highlights, Features, and News & Views, which cover significant advances in the field and topical issues. Nature Reviews Physics is published monthly from January 2019 and does not have external, academic editors. Instead, all editorial decisions are made by a dedicated team of full-time professional editors.
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