有机光伏器件中空穴和电子转移后的电荷转移态动力学

Charge-Transfer State Dynamics Following Hole and Electron Transfer in Organic Photovoltaic Devices.

作者信息

Bakulin Artem A, Dimitrov Stoichko D, Rao Akshay, Chow Philip C Y, Nielsen Christian B, Schroeder Bob C, McCulloch Iain, Bakker Huib J, Durrant James R, Friend Richard H

机构信息

†FOM Institute AMOLF, Science Park 104, Amsterdam, The Netherlands.

‡Cavendish Laboratory, University of Cambridge, JJ Thomson Ave, Cambridge CB3 0HE, United Kingdom.

出版信息

J Phys Chem Lett. 2013 Jan 3;4(1):209-15. doi: 10.1021/jz301883y. Epub 2012 Dec 26.

DOI:10.1021/jz301883y

PMID:26291233

Abstract

The formation of bound electron-hole pairs, also called charge-transfer (CT) states, in organic-based photovoltaic devices is one of the dominant loss mechanisms hindering performance. Whereas CT state dynamics following electron transfer from donor to acceptor have been widely studied, there is not much known about the dynamics of bound CT states produced by hole transfer from the acceptor to the donor. In this letter, we compare the dynamics of CT states formed in the different charge-transfer pathways in a range of model systems. We show that the nature and dynamics of the generated CT states are similar in the case of electron and hole transfer. However the yield of bound and free charges is observed to be strongly dependent on the HOMOD-HOMOA and LUMOD-LUMOA energy differences of the material system. We propose a qualitative model in which the effects of static disorder and sampling of states during the relaxation determine the probability of accessing CT states favorable for charge separation.

摘要

在有机基光伏器件中，束缚电子 - 空穴对（也称为电荷转移（CT）态）的形成是阻碍器件性能的主要损耗机制之一。尽管从供体到受体的电子转移后的CT态动力学已得到广泛研究，但对于从受体到供体的空穴转移产生的束缚CT态的动力学了解甚少。在这封信中，我们比较了一系列模型系统中不同电荷转移途径形成的CT态的动力学。我们表明，在电子转移和空穴转移的情况下，所产生的CT态的性质和动力学是相似的。然而，观察到束缚电荷和自由电荷的产率强烈依赖于材料系统的HOMOD - HOMOA和LUMOD - LUMOA能量差。我们提出了一个定性模型，其中静态无序和弛豫过程中态的采样效应决定了进入有利于电荷分离的CT态的概率。

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有机光伏器件中空穴和电子转移后的电荷转移态动力学

Charge-Transfer State Dynamics Following Hole and Electron Transfer in Organic Photovoltaic Devices.

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