Theory of coherent phonons coupled to excitons

IF 9.1 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

npj 2D Materials and Applications Pub Date : 2024-06-20 DOI:10.1038/s41699-024-00474-9

Enrico Perfetto, Kai Wu, Gianluca Stefanucci

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Abstract

The interaction of excitons with lattice vibrations underlies the scattering from bright to dark excitons as well as the coherent modulation of the exciton energy. Unlike the former mechanism, which involves phonons with finite momentum, the latter can be exclusively attributed to coherent phonons with zero momentum. We here lay down the microscopic theory of coherent phonons interacting with resonantly pumped bright excitons and provide the explicit expression of the corresponding coupling. The coupling notably resembles the exciton-phonon one, but with a crucial distinction: it contains the bare electron-phonon matrix elements rather than the screened ones. Our theory predicts that the exciton energy features a polaronic-like red-shift and monochromatic oscillations or beatings, depending on the number of coupled optical modes. Both the red-shift and the amplitude of the oscillations are proportional to the excitation density and to the square of the exciton-coherent-phonon coupling. We validate our analytical findings through comparisons with numerical simulations of time-resolved optical absorbance in resonantly pumped MoS2 monolayers.

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与激子耦合的相干声子理论

激子与晶格振动的相互作用是亮激子向暗激子散射以及激子能量相干调制的基础。前者涉及具有有限动量的声子，而后者则完全归因于具有零动量的相干声子。我们在此阐述了相干声子与共振泵浦亮激子相互作用的微观理论，并提供了相应耦合的明确表达式。该耦合与激子-声子耦合非常相似，但有一个重要区别：它包含裸电子-声子矩阵元素，而不是屏蔽元素。根据我们的理论预测，激子能量具有类似极子的红移和单色振荡或跳动，这取决于耦合光学模式的数量。红移和振荡幅度都与激发密度和激子-相干-声子耦合的平方成正比。我们通过与共振泵浦 MoS2 单层中时间分辨光吸收的数值模拟进行比较，验证了我们的分析结果。

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

npj 2D Materials and Applications Engineering-Mechanics of Materials

CiteScore

14.50

自引率

2.10%

发文量

审稿时长

15 weeks

期刊介绍： npj 2D Materials and Applications publishes papers on the fundamental behavior, synthesis, properties and applications of existing and emerging 2D materials. By selecting papers with the potential for impact, the journal aims to facilitate the transfer of the research of 2D materials into wide-ranging applications.