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Main Authors: Kaman, Jack, Musterman, Evan, Kelley, Kyle P., Domingo-Marimon, Neus, Dierolf, Volkmar, Jain, Himanshu
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.13221
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author Kaman, Jack
Musterman, Evan
Kelley, Kyle P.
Domingo-Marimon, Neus
Dierolf, Volkmar
Jain, Himanshu
author_facet Kaman, Jack
Musterman, Evan
Kelley, Kyle P.
Domingo-Marimon, Neus
Dierolf, Volkmar
Jain, Himanshu
contents Antimony sulfide is an emerging phase change material for optical and electrical memory and computation elements. It has additionally been reported as a ferroelectric, with recent evidence from hysteresis in piezoresponse force microscopy. Here, we complete a rigorous set of piezoresponse force microscopy experiments on a congruently crystallized Sb2S3 glass-ceramic, where piezoelectric coupling should be forbidden in glassy Sb2S3. We replicate previous results and reveal that the behavior is absent in glassy Sb2S3 but show that the response originates primarily from non-piezoelectric contributions to the signal caused by an applied voltage. This hysteretic behavior in piezoresponse force microscopy is quite similar to some electrochemically active non-ferroelectric oxides, but uniquely, it appears here with a very clear spatial contrast that is decoupled from surface topography. This shows that the electromechanical signal reflects bulk-like properties and reveals differences in electrical behavior of crystalline and amorphous phases of Sb2S3.
format Preprint
id arxiv_https___arxiv_org_abs_2603_13221
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Electromechanical Hysteresis in Phase Change Material Sb2S3
Kaman, Jack
Musterman, Evan
Kelley, Kyle P.
Domingo-Marimon, Neus
Dierolf, Volkmar
Jain, Himanshu
Materials Science
Antimony sulfide is an emerging phase change material for optical and electrical memory and computation elements. It has additionally been reported as a ferroelectric, with recent evidence from hysteresis in piezoresponse force microscopy. Here, we complete a rigorous set of piezoresponse force microscopy experiments on a congruently crystallized Sb2S3 glass-ceramic, where piezoelectric coupling should be forbidden in glassy Sb2S3. We replicate previous results and reveal that the behavior is absent in glassy Sb2S3 but show that the response originates primarily from non-piezoelectric contributions to the signal caused by an applied voltage. This hysteretic behavior in piezoresponse force microscopy is quite similar to some electrochemically active non-ferroelectric oxides, but uniquely, it appears here with a very clear spatial contrast that is decoupled from surface topography. This shows that the electromechanical signal reflects bulk-like properties and reveals differences in electrical behavior of crystalline and amorphous phases of Sb2S3.
title Electromechanical Hysteresis in Phase Change Material Sb2S3
topic Materials Science
url https://arxiv.org/abs/2603.13221