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Autores principales: Yang, Si Hyeok, Oh, Lim Kyung, Lee, Na Young, Lee, Dong Ho, Choi, Sang Min, Oh, Bowon, Park, Yun Ji, Cho, Yunji, Ryu, Jaesel, Kim, Hongki, Chin, Sang-Hyun, Yi, Yeonjin, Song, Myungkwan, Kim, Han Seul, Choi, Jin Woo
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2510.23063
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author Yang, Si Hyeok
Oh, Lim Kyung
Lee, Na Young
Lee, Dong Ho
Choi, Sang Min
Oh, Bowon
Park, Yun Ji
Cho, Yunji
Ryu, Jaesel
Kim, Hongki
Chin, Sang-Hyun
Yi, Yeonjin
Song, Myungkwan
Kim, Han Seul
Choi, Jin Woo
author_facet Yang, Si Hyeok
Oh, Lim Kyung
Lee, Na Young
Lee, Dong Ho
Choi, Sang Min
Oh, Bowon
Park, Yun Ji
Cho, Yunji
Ryu, Jaesel
Kim, Hongki
Chin, Sang-Hyun
Yi, Yeonjin
Song, Myungkwan
Kim, Han Seul
Choi, Jin Woo
contents Molecular zero-dimensional (0D) halide perovskite-inspired cesium copper iodide (Cs3Cu2I5) is a highly promising candidate for optoelectronic applications due to their low toxicity, high stability, and intense blue emission. However, their intrinsically poor electrical conductivity, stemming from isolated conductive copper iodide tetrahedra by cesium atoms, severely limits charge transport which poses a critical challenge for optoelectronic applications. In this study, we propose a novel strategy to overcome this limitation by utilizing precisely optimized zinc oxide nanoripple structures within a lateral Cs3Cu2I5 photodetector (PD) architecture featuring interdigitated electrodes (IDEs). The ZnO nanoripple was systematically tuned to improve the percolation paths, providing efficient routes for photogenerated carriers to migrate to the IDEs. Consequently, the optimized heterojunctions comprising Cs3Cu2I5 and ZnO exhibited superior photocurrent compared to the pristine Cs3Cu2I5 counterparts. This nanostructure-mediated charge transport engineering strategy for lateral structured PDs offers a new pathway for utilizing low-conductivity 0D materials for conventional optoelectronics, next-generation Internet of Things sensor networks, and plausibly biosensing applications.
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spellingShingle Amplified Photocurrent in Heterojunctions comprising Nano-rippled Zinc Oxide and Perovskite-inspired Cs3Cu2I5
Yang, Si Hyeok
Oh, Lim Kyung
Lee, Na Young
Lee, Dong Ho
Choi, Sang Min
Oh, Bowon
Park, Yun Ji
Cho, Yunji
Ryu, Jaesel
Kim, Hongki
Chin, Sang-Hyun
Yi, Yeonjin
Song, Myungkwan
Kim, Han Seul
Choi, Jin Woo
Materials Science
Molecular zero-dimensional (0D) halide perovskite-inspired cesium copper iodide (Cs3Cu2I5) is a highly promising candidate for optoelectronic applications due to their low toxicity, high stability, and intense blue emission. However, their intrinsically poor electrical conductivity, stemming from isolated conductive copper iodide tetrahedra by cesium atoms, severely limits charge transport which poses a critical challenge for optoelectronic applications. In this study, we propose a novel strategy to overcome this limitation by utilizing precisely optimized zinc oxide nanoripple structures within a lateral Cs3Cu2I5 photodetector (PD) architecture featuring interdigitated electrodes (IDEs). The ZnO nanoripple was systematically tuned to improve the percolation paths, providing efficient routes for photogenerated carriers to migrate to the IDEs. Consequently, the optimized heterojunctions comprising Cs3Cu2I5 and ZnO exhibited superior photocurrent compared to the pristine Cs3Cu2I5 counterparts. This nanostructure-mediated charge transport engineering strategy for lateral structured PDs offers a new pathway for utilizing low-conductivity 0D materials for conventional optoelectronics, next-generation Internet of Things sensor networks, and plausibly biosensing applications.
title Amplified Photocurrent in Heterojunctions comprising Nano-rippled Zinc Oxide and Perovskite-inspired Cs3Cu2I5
topic Materials Science
url https://arxiv.org/abs/2510.23063