Ab initio modeling of excitons: from perfect crystals to biomaterials

IF 7.7 2区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Advances in Physics: X Pub Date : 2021-01-01 DOI:10.1080/23746149.2021.1912638
G. Tirimbò, B. Baumeier
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引用次数: 2

Abstract

ABSTRACT Excitons, or coupled electron-hole excitations, are important both for fundamental optical properties of materials as well as and for the functionality of materials in opto-electronic devices. Depending on the material they are created in, excitons can come in many forms, from Wannier–Mott excitons in inorganic semiconductors, to molecular Frenkel or bi-molecular charge-transfer excitons in disordered organic or biological heterostructures. This multitude of materials and exciton types poses tremendous challenges for ab initio modeling. Following a brief overview of typical ab initio techniques, we summarize our recent work based on Many-Body Green’s Functions Theory in the GW approximation and Bethe–Salpeter Equation (BSE) as a method applicable to a wide range of material classes from perfect crystals to disordered materials. In particular, we emphasize the current challenges of embedding this GW-BSE method into multi-method, mixed quantum-classical (QM/MM) models for organic materials and illustrate them with examples from organic photovoltaics and fluorescence spectroscopy. Our perspectives on future studies are also presented. Graphical Abstract
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从头算激子建模:从完美晶体到生物材料
摘要激子,或称耦合电子-空穴激发,对材料的基本光学性质以及材料在光电器件中的功能都很重要。根据产生激子的材料,激子可以有多种形式,从无机半导体中的Wannier–Mott激子,到无序有机或生物异质结构中的分子Frenkel或双分子电荷转移激子。这种大量的材料和激子类型对从头算建模提出了巨大的挑战。在简要概述了典型的从头算技术之后,我们总结了我们最近基于GW近似中的多体格林函数理论和Bethe–Salpeter方程(BSE)的工作,该方法适用于从完美晶体到无序材料的广泛材料类别。特别是,我们强调了将这种GW-BSE方法嵌入有机材料的多方法混合量子经典(QM/MM)模型中的当前挑战,并用有机光伏和荧光光谱的例子进行了说明。还介绍了我们对未来研究的看法。图形摘要
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来源期刊
Advances in Physics: X
Advances in Physics: X Physics and Astronomy-General Physics and Astronomy
CiteScore
13.60
自引率
0.00%
发文量
37
审稿时长
13 weeks
期刊介绍: Advances in Physics: X is a fully open-access journal that promotes the centrality of physics and physical measurement to modern science and technology. Advances in Physics: X aims to demonstrate the interconnectivity of physics, meaning the intellectual relationships that exist between one branch of physics and another, as well as the influence of physics across (hence the “X”) traditional boundaries into other disciplines including: Chemistry Materials Science Engineering Biology Medicine
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