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Main Authors: Afrid, Sheikh Mohd Ta-Seen, Zhao, He Lin, van der Zande, Arend M., Rakheja, Shaloo
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.08975
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author Afrid, Sheikh Mohd Ta-Seen
Zhao, He Lin
van der Zande, Arend M.
Rakheja, Shaloo
author_facet Afrid, Sheikh Mohd Ta-Seen
Zhao, He Lin
van der Zande, Arend M.
Rakheja, Shaloo
contents Strain fundamentally alters carrier transport in semiconductors by modifying their band structure and scattering pathways. In transition-metal dichalcogenides (TMDs), an emerging class of 2D semiconductors, we show that mobility modulation under biaxial strain is dictated by changes in inter-valley scattering rather than effective mass renormalization as in bulk silicon. Using a multiscale full-band transport framework that incorporates both intrinsic phonon, extrinsic impurity, and dielectric scattering, we find that tensile strain enhances n-type mobility through K-Q valley separation, while compressive strain improves p-type mobility via Γ-K decoupling. The tuning rates calculated from our full-band model far exceed those achieved by strain engineering in silicon. Both relaxed and strain-modulated carrier mobilities align quantitatively with experimentally verified measurements and are valid across a wide range of practical FET configurations. The enhancement remains robust across variations in temperature, carrier density, impurity level, and dielectric environment. Our results highlight the pivotal role of strain in improving the reliability and performance of 2D TMD-based electronics.
format Preprint
id arxiv_https___arxiv_org_abs_2511_08975
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Strain-tunable inter-valley scattering defines universal mobility enhancement in n- and p-type 2D TMDs
Afrid, Sheikh Mohd Ta-Seen
Zhao, He Lin
van der Zande, Arend M.
Rakheja, Shaloo
Applied Physics
Strain fundamentally alters carrier transport in semiconductors by modifying their band structure and scattering pathways. In transition-metal dichalcogenides (TMDs), an emerging class of 2D semiconductors, we show that mobility modulation under biaxial strain is dictated by changes in inter-valley scattering rather than effective mass renormalization as in bulk silicon. Using a multiscale full-band transport framework that incorporates both intrinsic phonon, extrinsic impurity, and dielectric scattering, we find that tensile strain enhances n-type mobility through K-Q valley separation, while compressive strain improves p-type mobility via Γ-K decoupling. The tuning rates calculated from our full-band model far exceed those achieved by strain engineering in silicon. Both relaxed and strain-modulated carrier mobilities align quantitatively with experimentally verified measurements and are valid across a wide range of practical FET configurations. The enhancement remains robust across variations in temperature, carrier density, impurity level, and dielectric environment. Our results highlight the pivotal role of strain in improving the reliability and performance of 2D TMD-based electronics.
title Strain-tunable inter-valley scattering defines universal mobility enhancement in n- and p-type 2D TMDs
topic Applied Physics
url https://arxiv.org/abs/2511.08975