Dephasing of Strong-Field-Driven Excitonic Autler-Townes Doublets Revealed by Time- and Spectrum-Resolved Quantum-Path Interferometry

Yaxin Liu; Bingbing Zhu; Shicheng Jiang; Shenyang Huang; Mingyan Luo; Sheng Zhang; Hugen Yan; Yuanbo Zhang; Ruifeng Lu; Zhensheng Tao

doi:10.1103/PhysRevLett.133.026901

Dephasing of Strong-Field-Driven Excitonic Autler-Townes Doublets Revealed by Time- and Spectrum-Resolved Quantum-Path Interferometry

Yaxin Liu, Bingbing Zhu, Shicheng Jiang, Shenyang Huang, Mingyan Luo, Sheng Zhang, Hugen Yan, Yuanbo Zhang, Ruifeng Lu, Zhensheng Tao

Institute for Advanced Study in Precision Spectroscopy

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Understanding dephasing mechanisms of strong-field-driven excitons in condensed matter is essential for their applications in quantum-state manipulation and ultrafast optical modulations. However, experimental access to exciton dephasing under strong-field conditions is challenging. In this study, using time- and spectrum-resolved quantum-path interferometry, we investigate the dephasing mechanisms of terahertz-driven excitonic Autler-Townes doublets in MoS2. Our results reveal a dramatic increase in the dephasing rate beyond a threshold field strength, indicating exciton dissociation as the primary dephasing mechanism. Furthermore, we demonstrate nonperturbative high-order sideband generation in a regime where the driving fields are insufficient to dissociate excitons.

Original language	English
Article number	026901
Journal	Physical Review Letters
Volume	133
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.133.026901
State	Published - 12 Jul 2024

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title = "Dephasing of Strong-Field-Driven Excitonic Autler-Townes Doublets Revealed by Time- and Spectrum-Resolved Quantum-Path Interferometry",

abstract = "Understanding dephasing mechanisms of strong-field-driven excitons in condensed matter is essential for their applications in quantum-state manipulation and ultrafast optical modulations. However, experimental access to exciton dephasing under strong-field conditions is challenging. In this study, using time- and spectrum-resolved quantum-path interferometry, we investigate the dephasing mechanisms of terahertz-driven excitonic Autler-Townes doublets in MoS2. Our results reveal a dramatic increase in the dephasing rate beyond a threshold field strength, indicating exciton dissociation as the primary dephasing mechanism. Furthermore, we demonstrate nonperturbative high-order sideband generation in a regime where the driving fields are insufficient to dissociate excitons.",

author = "Yaxin Liu and Bingbing Zhu and Shicheng Jiang and Shenyang Huang and Mingyan Luo and Sheng Zhang and Hugen Yan and Yuanbo Zhang and Ruifeng Lu and Zhensheng Tao",

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doi = "10.1103/PhysRevLett.133.026901",

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T1 - Dephasing of Strong-Field-Driven Excitonic Autler-Townes Doublets Revealed by Time- and Spectrum-Resolved Quantum-Path Interferometry

AU - Liu, Yaxin

AU - Zhu, Bingbing

AU - Jiang, Shicheng

AU - Huang, Shenyang

AU - Luo, Mingyan

AU - Zhang, Sheng

AU - Yan, Hugen

AU - Zhang, Yuanbo

AU - Lu, Ruifeng

AU - Tao, Zhensheng

PY - 2024/7/12

Y1 - 2024/7/12

N2 - Understanding dephasing mechanisms of strong-field-driven excitons in condensed matter is essential for their applications in quantum-state manipulation and ultrafast optical modulations. However, experimental access to exciton dephasing under strong-field conditions is challenging. In this study, using time- and spectrum-resolved quantum-path interferometry, we investigate the dephasing mechanisms of terahertz-driven excitonic Autler-Townes doublets in MoS2. Our results reveal a dramatic increase in the dephasing rate beyond a threshold field strength, indicating exciton dissociation as the primary dephasing mechanism. Furthermore, we demonstrate nonperturbative high-order sideband generation in a regime where the driving fields are insufficient to dissociate excitons.

AB - Understanding dephasing mechanisms of strong-field-driven excitons in condensed matter is essential for their applications in quantum-state manipulation and ultrafast optical modulations. However, experimental access to exciton dephasing under strong-field conditions is challenging. In this study, using time- and spectrum-resolved quantum-path interferometry, we investigate the dephasing mechanisms of terahertz-driven excitonic Autler-Townes doublets in MoS2. Our results reveal a dramatic increase in the dephasing rate beyond a threshold field strength, indicating exciton dissociation as the primary dephasing mechanism. Furthermore, we demonstrate nonperturbative high-order sideband generation in a regime where the driving fields are insufficient to dissociate excitons.

UR - https://www.scopus.com/pages/publications/85198902269

U2 - 10.1103/PhysRevLett.133.026901

DO - 10.1103/PhysRevLett.133.026901

M3 - 文章

C2 - 39073979

AN - SCOPUS:85198902269

SN - 0031-9007

VL - 133

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Dephasing of Strong-Field-Driven Excitonic Autler-Townes Doublets Revealed by Time- and Spectrum-Resolved Quantum-Path Interferometry

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