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Main Authors: Wan, Qiang, Zhao, Keming, Dong, Guohao, Li, Enting, Yang, Tianyu, Wang, Hao, Huang, Yaobo, Wen, Yao, Li, Yiwei, He, Jun, Shi, Youguo, Ding, Hong, Xu, Nan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.08279
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author Wan, Qiang
Zhao, Keming
Dong, Guohao
Li, Enting
Yang, Tianyu
Wang, Hao
Huang, Yaobo
Wen, Yao
Li, Yiwei
He, Jun
Shi, Youguo
Ding, Hong
Xu, Nan
author_facet Wan, Qiang
Zhao, Keming
Dong, Guohao
Li, Enting
Yang, Tianyu
Wang, Hao
Huang, Yaobo
Wen, Yao
Li, Yiwei
He, Jun
Shi, Youguo
Ding, Hong
Xu, Nan
contents Benefit to layer-dependent bandgap, van der Waals materials with surface photovoltaic effect (SPV) enable photodetection over a tunable wavelength range with low power consumption. However, sensitive SPV in the infrared region, especially in a quasi-steady illumination condition, is still elusive in layered semiconductors. Here, using angle-resolved photoemission spectroscopy, we report a sensitive SPV in quasi-equilibrium in NbSi0.5Te2, with photoresponsivity up to 2.4*10^6 V/(W*cm^(-2)) at low intensity low temperature condition (LILT). The sensitive SPV is further confirmed by observing the Dember effect, where the photogenerated carrier density is high enough and diffusion currents suppress SPV. Temperature-dependent measurements indicate that intrinsic carriers freezing at low temperature leads to the ultrahigh photoresponse, while a small amount of photon-generated carriers in quasi-equilibrium dominate the system. Our work not only provides a promising layered semiconductor for Infrared optoelectronic devices with strong infrared SPV at LILT, which has application potential in fields such as quantum information and deep-space exploration, but also paves a novel way to enhance light-matter interaction effect by freezing bulk carriers.
format Preprint
id arxiv_https___arxiv_org_abs_2507_08279
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sensitive infrared surface photovoltage in quasi-equilibrium in a layered semiconductor at low-intensity low-temperature condition
Wan, Qiang
Zhao, Keming
Dong, Guohao
Li, Enting
Yang, Tianyu
Wang, Hao
Huang, Yaobo
Wen, Yao
Li, Yiwei
He, Jun
Shi, Youguo
Ding, Hong
Xu, Nan
Materials Science
Mesoscale and Nanoscale Physics
Benefit to layer-dependent bandgap, van der Waals materials with surface photovoltaic effect (SPV) enable photodetection over a tunable wavelength range with low power consumption. However, sensitive SPV in the infrared region, especially in a quasi-steady illumination condition, is still elusive in layered semiconductors. Here, using angle-resolved photoemission spectroscopy, we report a sensitive SPV in quasi-equilibrium in NbSi0.5Te2, with photoresponsivity up to 2.4*10^6 V/(W*cm^(-2)) at low intensity low temperature condition (LILT). The sensitive SPV is further confirmed by observing the Dember effect, where the photogenerated carrier density is high enough and diffusion currents suppress SPV. Temperature-dependent measurements indicate that intrinsic carriers freezing at low temperature leads to the ultrahigh photoresponse, while a small amount of photon-generated carriers in quasi-equilibrium dominate the system. Our work not only provides a promising layered semiconductor for Infrared optoelectronic devices with strong infrared SPV at LILT, which has application potential in fields such as quantum information and deep-space exploration, but also paves a novel way to enhance light-matter interaction effect by freezing bulk carriers.
title Sensitive infrared surface photovoltage in quasi-equilibrium in a layered semiconductor at low-intensity low-temperature condition
topic Materials Science
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2507.08279