Anomalous photovoltaics in Janus MoSSe monolayers

Chang Liu; Tianyu Liang; Xin Sui; Lena Du; Quanlin Guo; Guodong Xue; Chen Huang; Yilong You; Guangjie Yao; Mengze Zhao; Jianbo Yin; Zhipei Sun; Hao Hong; Enge Wang; Kaihui Liu

doi:10.1038/s41467-024-55623-x

Anomalous photovoltaics in Janus MoSSe monolayers

Chang Liu, Tianyu Liang, Xin Sui, Lena Du, Quanlin Guo, Guodong Xue, Chen Huang, Yilong You, Guangjie Yao, Mengze Zhao, Jianbo Yin, Zhipei Sun, Hao Hong, Enge Wang, Kaihui Liu

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Abstract

The anomalous photovoltaic effect (APE) in polar crystals is a promising avenue for overcoming the energy conversion efficiency limits of conventional photoelectric devices utilizing p-n junction architectures. To facilitate effective photocarrier separation and enhance the APE, polar materials need to be thinned down to maximize the depolarization field. Here, we demonstrate Janus MoSSe monolayers (~0.67 nm thick) with strong spontaneous photocurrent generation. A photoresponsivity up to 3 mA/W, with ~ 1% external quantum efficiency and ultrafast photoresponse (~50 ps) were observed in the MoSSe device. Moreover, unlike conventional 2D materials that require careful twist alignment, the photovoltage can be further scaled up by simply stacking the MoSSe layers without the need for specific control on interlayer twist angles. Our work paves the way for the development of high-performance, flexible, and compact photovoltaics and optoelectronics with atomically engineered Janus polar materials.

Original language	English
Article number	544
Pages (from-to)	544
Number of pages	1
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-55623-x
Publication status	Published - 9 Jan 2025
MoE publication type	A1 Journal article-refereed

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s41467-024-55623-xFinal published version, 2.04 MBLicence: CC BY-NC-ND

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title = "Anomalous photovoltaics in Janus MoSSe monolayers",

abstract = "The anomalous photovoltaic effect (APE) in polar crystals is a promising avenue for overcoming the energy conversion efficiency limits of conventional photoelectric devices utilizing p-n junction architectures. To facilitate effective photocarrier separation and enhance the APE, polar materials need to be thinned down to maximize the depolarization field. Here, we demonstrate Janus MoSSe monolayers (~0.67 nm thick) with strong spontaneous photocurrent generation. A photoresponsivity up to 3 mA/W, with ~ 1% external quantum efficiency and ultrafast photoresponse (~50 ps) were observed in the MoSSe device. Moreover, unlike conventional 2D materials that require careful twist alignment, the photovoltage can be further scaled up by simply stacking the MoSSe layers without the need for specific control on interlayer twist angles. Our work paves the way for the development of high-performance, flexible, and compact photovoltaics and optoelectronics with atomically engineered Janus polar materials.",

author = "Chang Liu and Tianyu Liang and Xin Sui and Lena Du and Quanlin Guo and Guodong Xue and Chen Huang and Yilong You and Guangjie Yao and Mengze Zhao and Jianbo Yin and Zhipei Sun and Hao Hong and Enge Wang and Kaihui Liu",

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AU - Liu, Chang

AU - Liang, Tianyu

AU - Sui, Xin

AU - Du, Lena

AU - Guo, Quanlin

AU - Xue, Guodong

AU - Huang, Chen

AU - You, Yilong

AU - Yao, Guangjie

AU - Zhao, Mengze

AU - Yin, Jianbo

AU - Sun, Zhipei

AU - Hong, Hao

AU - Wang, Enge

AU - Liu, Kaihui

PY - 2025/1/9

Y1 - 2025/1/9

N2 - The anomalous photovoltaic effect (APE) in polar crystals is a promising avenue for overcoming the energy conversion efficiency limits of conventional photoelectric devices utilizing p-n junction architectures. To facilitate effective photocarrier separation and enhance the APE, polar materials need to be thinned down to maximize the depolarization field. Here, we demonstrate Janus MoSSe monolayers (~0.67 nm thick) with strong spontaneous photocurrent generation. A photoresponsivity up to 3 mA/W, with ~ 1% external quantum efficiency and ultrafast photoresponse (~50 ps) were observed in the MoSSe device. Moreover, unlike conventional 2D materials that require careful twist alignment, the photovoltage can be further scaled up by simply stacking the MoSSe layers without the need for specific control on interlayer twist angles. Our work paves the way for the development of high-performance, flexible, and compact photovoltaics and optoelectronics with atomically engineered Janus polar materials.

AB - The anomalous photovoltaic effect (APE) in polar crystals is a promising avenue for overcoming the energy conversion efficiency limits of conventional photoelectric devices utilizing p-n junction architectures. To facilitate effective photocarrier separation and enhance the APE, polar materials need to be thinned down to maximize the depolarization field. Here, we demonstrate Janus MoSSe monolayers (~0.67 nm thick) with strong spontaneous photocurrent generation. A photoresponsivity up to 3 mA/W, with ~ 1% external quantum efficiency and ultrafast photoresponse (~50 ps) were observed in the MoSSe device. Moreover, unlike conventional 2D materials that require careful twist alignment, the photovoltage can be further scaled up by simply stacking the MoSSe layers without the need for specific control on interlayer twist angles. Our work paves the way for the development of high-performance, flexible, and compact photovoltaics and optoelectronics with atomically engineered Janus polar materials.

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Anomalous photovoltaics in Janus MoSSe monolayers

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Anomalous photovoltaics in Janus MoSSe monolayers

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