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Main Authors: Biswasray, Debasish, Singh, Yogendra, Biswal, Amar Jyoti, Mariserla, Bala Murali Krishna
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.23500
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author Biswasray, Debasish
Singh, Yogendra
Biswal, Amar Jyoti
Mariserla, Bala Murali Krishna
author_facet Biswasray, Debasish
Singh, Yogendra
Biswal, Amar Jyoti
Mariserla, Bala Murali Krishna
contents Controllable quasiparticle radiation in two-dimensional (2D) semiconductors is essential for efficient carrier recombination, tunable emission, and modulation of valley polarization which are strongly determined by both the density and nature of underlying excitonic species. Conventional chemical doping techniques, however, often hinder the reversibility and density of excitonic charge states (exciton and trion) due to unfavorable interactions between dopant and 2D materials. In this work, efficient excitonic charge state conversion is achieved by doping monolayer WS$_2$ using water rinsed PVA and the quasiparticle densities are further enhanced by applying high periodic biaxial strain (up to 2.3%) through a 2D silica microsphere array. The method presented here enables nearly 100% reversible trion-to-exciton conversion without the need of electrostatic gating, while delivering thermally stable trions with a large binding energy of ~56 meV and a high free electron density of ~3$\times$10$^{13}$ cm$^{-2}$ at room temperature. Strain-induced funneling of the PVA-injected free electrons substantially increases the excitonic quasiparticle densities and boosts the trion emission by 41%. Overall, this approach establishes a versatile platform for excitonic charge state conversion and enhanced quasiparticle density in 2D materials, offering promising opportunities for future optical data storage, quantum-light and display technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2512_23500
institution arXiv
publishDate 2025
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spellingShingle Reversible Excitonic Charge State Conversion and High Quasiparticle Densities in PVA-doped Monolayer WS$_2$ on 2D Microsphere Array
Biswasray, Debasish
Singh, Yogendra
Biswal, Amar Jyoti
Mariserla, Bala Murali Krishna
Mesoscale and Nanoscale Physics
Controllable quasiparticle radiation in two-dimensional (2D) semiconductors is essential for efficient carrier recombination, tunable emission, and modulation of valley polarization which are strongly determined by both the density and nature of underlying excitonic species. Conventional chemical doping techniques, however, often hinder the reversibility and density of excitonic charge states (exciton and trion) due to unfavorable interactions between dopant and 2D materials. In this work, efficient excitonic charge state conversion is achieved by doping monolayer WS$_2$ using water rinsed PVA and the quasiparticle densities are further enhanced by applying high periodic biaxial strain (up to 2.3%) through a 2D silica microsphere array. The method presented here enables nearly 100% reversible trion-to-exciton conversion without the need of electrostatic gating, while delivering thermally stable trions with a large binding energy of ~56 meV and a high free electron density of ~3$\times$10$^{13}$ cm$^{-2}$ at room temperature. Strain-induced funneling of the PVA-injected free electrons substantially increases the excitonic quasiparticle densities and boosts the trion emission by 41%. Overall, this approach establishes a versatile platform for excitonic charge state conversion and enhanced quasiparticle density in 2D materials, offering promising opportunities for future optical data storage, quantum-light and display technologies.
title Reversible Excitonic Charge State Conversion and High Quasiparticle Densities in PVA-doped Monolayer WS$_2$ on 2D Microsphere Array
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2512.23500