Seungho Bang, Wooyoung Kang, Dohyeong Kim, Hyeong Chan Suh, Dong Hyeon Kim, Chan Kwon, Jieun Jo, Ji-Hong Kim, Hayoung Ko, Ki Kang Kim, Jinho Ahn, Mun Seok Jeong
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引用次数: 0
摘要
最近,人们探索了基于二维半导体的光电存储器,通过将光学传感和数据存储集成到一个器件中,克服了传统冯-诺依曼架构的局限性。持续光电流(PPC)是光电存储器的关键,它源自二维半导体中的肖克利-雷德-霍尔(SRH)模型中的电荷载流子捕获。准费米级位置会影响电荷捕获点的激活。然而,二维半导体中准费米级调制与 PPC 之间的相关性尚未得到广泛研究。在这项研究中,我们展示了基于二维半导体-聚合物混合结构的光电存储器,并证实其基本机制是电荷捕获,正如 SRH 模型所解释的那样。在光照下,电子从聚乙烯吡咯烷酮转移到 p 型二硒化钨,导致高电平注入和多数载流子型转变。我们的发现为优化基于二维半导体的光电存储器提供了宝贵的见解。
Harnessing Persistent Photocurrent in a 2D Semiconductor-Polymer Hybrid Structure: Electron Trapping and Fermi Level Modulation for Optoelectronic Memory.
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.
期刊介绍:
Nano Letters serves as a dynamic platform for promptly disseminating original results in fundamental, applied, and emerging research across all facets of nanoscience and nanotechnology. A pivotal criterion for inclusion within Nano Letters is the convergence of at least two different areas or disciplines, ensuring a rich interdisciplinary scope. The journal is dedicated to fostering exploration in diverse areas, including:
- Experimental and theoretical findings on physical, chemical, and biological phenomena at the nanoscale
- Synthesis, characterization, and processing of organic, inorganic, polymer, and hybrid nanomaterials through physical, chemical, and biological methodologies
- Modeling and simulation of synthetic, assembly, and interaction processes
- Realization of integrated nanostructures and nano-engineered devices exhibiting advanced performance
- Applications of nanoscale materials in living and environmental systems
Nano Letters is committed to advancing and showcasing groundbreaking research that intersects various domains, fostering innovation and collaboration in the ever-evolving field of nanoscience and nanotechnology.