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Harnessing Persistent Photocurrent in a 2D Semiconductor-Polymer Hybrid Structure: Electron Trapping and Fermi Level Modulation for Optoelectronic MemoryHarnessing Persistent Photocurrent in a 2D Semiconductor–Polymer Hybrid Structure: Electron Trapping and Fermi Level Modulation for Optoelectronic Memory

Other Titles
Harnessing Persistent Photocurrent in a 2D Semiconductor–Polymer Hybrid Structure: Electron Trapping and Fermi Level Modulation for Optoelectronic Memory
Authors
Bang, SeunghoKang, WooyoungKim, DohyeongSuh, Hyeong ChanKim, Dong HyeonKwon, ChanJo, JieunKim, Ji-HongKo, HayoungKim, Ki KangAhn, JinhoJeong, Mun Seok
Issue Date
Jul-2024
Publisher
American Chemical Society
Keywords
persistent photocurrent; high-level injection; photogating effect; trap site; Shockley-Read-Hallmodel
Citation
Nano Letters, v.24, no.32, pp 9889 - 9897
Pages
9
Indexed
SCIE
SCOPUS
Journal Title
Nano Letters
Volume
24
Number
32
Start Page
9889
End Page
9897
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/210087
DOI
10.1021/acs.nanolett.4c02173
ISSN
1530-6984
1530-6992
Abstract
Recently, 2D semiconductor-based optoelectronic memory has been explored to overcome the limitations of conventional von Neumann architectures by integrating optical sensing and data storage into one device. Persistent photocurrent (PPC), essential for optoelectronic memory, originates from charge carrier trapping according to the Shockley–Read–Hall (SRH) model in 2D semiconductors. The quasi-Fermi level position influences the activation of charge-trapping sites. However, the correlation between quasi-Fermi level modulations and PPC in 2D semiconductors has not been extensively studied. In this study, we demonstrate optoelectronic memory based on a 2D semiconductor–polymer hybrid structure and confirm that the underlying mechanism is charge trapping, as the SRH model explains. Under light illumination, electrons transfer from polyvinylpyrrolidone to p-type tungsten diselenide, resulting in high-level injection and majority carrier-type transitions. The quasi-Fermi level shifts upward with increasing temperature, improving PPC and enabling optoelectronic memory at 433 K. Our findings offer valuable insights into optimizing 2D semiconductor-based optoelectronic memory.
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