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Auteurs principaux: Murray, Lottie L., Herrmann, Eric, Evangelista, Igor, Janotti, Anderson, Wang, Xi, Doty, Matthew F.
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2601.08984
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author Murray, Lottie L.
Herrmann, Eric
Evangelista, Igor
Janotti, Anderson
Wang, Xi
Doty, Matthew F.
author_facet Murray, Lottie L.
Herrmann, Eric
Evangelista, Igor
Janotti, Anderson
Wang, Xi
Doty, Matthew F.
contents We present a rigorous analysis that combines theory, simulation, and experimental measurements to quantify the relationship between strain and bandgap in two dimensional gallium selenide (Ga$_2$Se$_2$). Experimentally, we transfer thin Ga$_2$Se$_2$ flakes onto patterned substrates to deterministically induce multiaxial localized strain. We quantify the local strain using a combination of atomic force microscopy (AFM) measurements and COMSOL Multiphysics simulation. We then experimentally map the strain-induced bandgap shifts using high-resolution hyperspectral PL imaging to generate a robust and statistically significant dataset. We systematically fit this data to extract gauge factors that relate the bandgap shift to the local uniaxial and biaxial strain. We then compute the uniaxial and biaxial strain gauge factors via density functional theory (DFT) and find excellent agreement with the experimentally-determined values. Finally, we show that a simple model that computes bandgap shifts from the local uniaxial and biaxial strain predicts the observed multiaxial bandgap shift with less than 10\% error. The combined results provide a framework for deterministic realization of tailored bandgap profiles induced by controlled strain applied to Ga$_2$Se$_2$, with implications for the future realization of localized quantum emitters for quantum photonic applications.
format Preprint
id arxiv_https___arxiv_org_abs_2601_08984
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantifying the Relationship Between Strain and Bandgap in Thin Ga$_2$Se$_2$
Murray, Lottie L.
Herrmann, Eric
Evangelista, Igor
Janotti, Anderson
Wang, Xi
Doty, Matthew F.
Materials Science
Quantum Physics
We present a rigorous analysis that combines theory, simulation, and experimental measurements to quantify the relationship between strain and bandgap in two dimensional gallium selenide (Ga$_2$Se$_2$). Experimentally, we transfer thin Ga$_2$Se$_2$ flakes onto patterned substrates to deterministically induce multiaxial localized strain. We quantify the local strain using a combination of atomic force microscopy (AFM) measurements and COMSOL Multiphysics simulation. We then experimentally map the strain-induced bandgap shifts using high-resolution hyperspectral PL imaging to generate a robust and statistically significant dataset. We systematically fit this data to extract gauge factors that relate the bandgap shift to the local uniaxial and biaxial strain. We then compute the uniaxial and biaxial strain gauge factors via density functional theory (DFT) and find excellent agreement with the experimentally-determined values. Finally, we show that a simple model that computes bandgap shifts from the local uniaxial and biaxial strain predicts the observed multiaxial bandgap shift with less than 10\% error. The combined results provide a framework for deterministic realization of tailored bandgap profiles induced by controlled strain applied to Ga$_2$Se$_2$, with implications for the future realization of localized quantum emitters for quantum photonic applications.
title Quantifying the Relationship Between Strain and Bandgap in Thin Ga$_2$Se$_2$
topic Materials Science
Quantum Physics
url https://arxiv.org/abs/2601.08984