Impact of n-Doping Mechanisms on the Molecular Packing and Electron Mobilities of Molecular Semiconductors for Organic Thermoelectrics

Yan Zeng, G. Han, Yuanping Yi
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引用次数: 1

Abstract

Electrical conductivity is one of the key parameters for organic thermoelectrics and depends on both the concentration and mobility of charge carriers. To increase the carrier concentration, molecular dopants have to be added into organic semiconductor materials, whereas the introduction of dopants can influence the molecular packing structures and hence carrier mobility of the organic semiconductors. Herein, we have theoretically investigated the impact of different n-doping mechanisms on molecular packing and electron transport properties by taking N-DMBI-H and Q-DCM-DPPTT respectively as representative n-dopant and molecular semiconductor. The results show that when the doping reactions and charge transfer spontaneously occur in the solution at room temperature, the oppositely charged dopant and semiconductor molecules will be tightly bound to disrupt the semiconductor to form long-range molecular packing, leading to a substantial decrease of electron mobility in the doped film. In contrast, when the doping reactions and charge transfer are activated by heating the doped film, the molecular packing of the semiconductor is slight affected and hence the electron mobility remains quite high. This work indicates that thermally-activated n-doping is an effective way to achieve both high carrier concentration and high electron mobility in n-type organic thermoelectric materials.

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n掺杂机制对有机热电材料分子半导体的分子堆积和电子迁移率的影响
电导率是有机热电的关键参数之一,它取决于载流子的浓度和迁移率。为了增加载流子浓度,必须将分子掺杂剂添加到有机半导体材料中,而掺杂剂的引入会影响有机半导体的分子堆积结构,从而影响载流子迁移率。在此,我们分别以n-DMBI-H和Q-DCM-DPPTT作为代表性的n-掺杂剂和分子半导体,从理论上研究了不同n-掺杂机制对分子堆积和电子传输性能的影响。结果表明,当室温下溶液中自发发生掺杂反应和电荷转移时,带相反电荷的掺杂剂和半导体分子会紧密结合,破坏半导体,形成长程分子堆积,导致掺杂膜中电子迁移率大幅降低。相反,当通过加热掺杂膜来激活掺杂反应和电荷转移时,半导体的分子堆积受到轻微影响,因此电子迁移率保持相当高。这项工作表明,热激活n掺杂是在n型有机热电材料中实现高载流子浓度和高电子迁移率的有效方法。
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来源期刊
CiteScore
3.70
自引率
0.00%
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0
审稿时长
12 weeks
期刊最新文献
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