Revealing exciton transport in atomically thin semiconductors

Fengjiang Liu; Kai Chen; Wei Yan; Weiwei Tang; Hao Zhang; Richard J. Blaikie; Yu Hui Chen; Boyang Ding; Min Qiu

doi:10.1103/PhysRevB.109.205418

Revealing exciton transport in atomically thin semiconductors

Fengjiang Liu
, Kai Chen
, Wei Yan
, Weiwei Tang
, Hao Zhang
, Richard J. Blaikie
, Yu Hui Chen
, Boyang Ding
, Min Qiu

School of Physics

Westlake University
Dodd-Walls Centre for Photonic and Quantum Technologies
MacDiarmid Institute for Advanced Materials and Nanotechnology
Victoria University of Wellington
University of Otago
Coherent Scientific Pty. Ltd.

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

Abstract

Exciton transport is a fundamental process that underlies the functionality of semiconductor optoelectronic devices. However, when excitons interact with one another, their transport pattern becomes unpredictable, posing a great challenge to harness their full potential in various applications. In our study, focusing on the exciton density change in a tungsten-disulfide monolayer, we observed that strong interactions between excitons can actually stop their movement. This finding contradicts the typical understanding of consistent exciton movement and reveals that a higher density might decrease the exciton-exciton annihilation rate due to reduced mobility. Our findings offer a valuable technique to examine exciton transport and deepen our grasp of their behavior in many-body interactions, which could pave the way for better-performing excitonic devices.

Original language	English
Article number	205418
Journal	Physical Review B
Volume	109
Issue number	20
DOIs	https://doi.org/10.1103/PhysRevB.109.205418
Publication status	Published - 15 May 2024

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10.1103/PhysRevB.109.205418

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title = "Revealing exciton transport in atomically thin semiconductors",

abstract = "Exciton transport is a fundamental process that underlies the functionality of semiconductor optoelectronic devices. However, when excitons interact with one another, their transport pattern becomes unpredictable, posing a great challenge to harness their full potential in various applications. In our study, focusing on the exciton density change in a tungsten-disulfide monolayer, we observed that strong interactions between excitons can actually stop their movement. This finding contradicts the typical understanding of consistent exciton movement and reveals that a higher density might decrease the exciton-exciton annihilation rate due to reduced mobility. Our findings offer a valuable technique to examine exciton transport and deepen our grasp of their behavior in many-body interactions, which could pave the way for better-performing excitonic devices.",

author = "Fengjiang Liu and Kai Chen and Wei Yan and Weiwei Tang and Hao Zhang and Blaikie, \{Richard J.\} and Chen, \{Yu Hui\} and Boyang Ding and Min Qiu",

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AU - Liu, Fengjiang

AU - Chen, Kai

AU - Yan, Wei

AU - Tang, Weiwei

AU - Zhang, Hao

AU - Blaikie, Richard J.

AU - Chen, Yu Hui

AU - Ding, Boyang

AU - Qiu, Min

PY - 2024/5/15

Y1 - 2024/5/15

N2 - Exciton transport is a fundamental process that underlies the functionality of semiconductor optoelectronic devices. However, when excitons interact with one another, their transport pattern becomes unpredictable, posing a great challenge to harness their full potential in various applications. In our study, focusing on the exciton density change in a tungsten-disulfide monolayer, we observed that strong interactions between excitons can actually stop their movement. This finding contradicts the typical understanding of consistent exciton movement and reveals that a higher density might decrease the exciton-exciton annihilation rate due to reduced mobility. Our findings offer a valuable technique to examine exciton transport and deepen our grasp of their behavior in many-body interactions, which could pave the way for better-performing excitonic devices.

AB - Exciton transport is a fundamental process that underlies the functionality of semiconductor optoelectronic devices. However, when excitons interact with one another, their transport pattern becomes unpredictable, posing a great challenge to harness their full potential in various applications. In our study, focusing on the exciton density change in a tungsten-disulfide monolayer, we observed that strong interactions between excitons can actually stop their movement. This finding contradicts the typical understanding of consistent exciton movement and reveals that a higher density might decrease the exciton-exciton annihilation rate due to reduced mobility. Our findings offer a valuable technique to examine exciton transport and deepen our grasp of their behavior in many-body interactions, which could pave the way for better-performing excitonic devices.

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DO - 10.1103/PhysRevB.109.205418

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SN - 2469-9950

VL - 109

JO - Physical Review B

JF - Physical Review B

IS - 20

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ER -

Revealing exciton transport in atomically thin semiconductors

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