Defect-Engineered Semiconducting van der Waals Thin Film at Metal–Semiconductor Interface of Field-Effect Transistors

Defect-Engineered Semiconducting van der Waals Thin Film at Metal–Semiconductor Interface of Field-Effect Transistors

The significance of metal–semiconductor interfaces and their impact on electronic device performance have gained increasing attention, with a particular focus on investigating the contact metal. However, another avenue of exploration involves substituting the contact metal at the metal–semiconductor...

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Veröffentlicht in:ACS nano 2024-01, Vol.18 (1), p.1073-1083
Hauptverfasser: Kim, Jihyun, Rhee, Dongjoon, Jung, Myeongjin, Cheon, Gang Jin, Kim, Kangsan, Kim, Jae Hyung, Park, Ji Yun, Yoon, Jiyong, Lim, Dong Un, Cho, Jeong Ho, Kim, In Soo, Son, Donghee, Jariwala, Deep, Kang, Joohoon
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container_issue 1
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container_title ACS nano
container_volume 18
creator Kim, Jihyun
Rhee, Dongjoon
Jung, Myeongjin
Cheon, Gang Jin
Kim, Kangsan
Kim, Jae Hyung
Park, Ji Yun
Yoon, Jiyong
Lim, Dong Un
Cho, Jeong Ho
Kim, In Soo
Son, Donghee
Jariwala, Deep
Kang, Joohoon
description The significance of metal–semiconductor interfaces and their impact on electronic device performance have gained increasing attention, with a particular focus on investigating the contact metal. However, another avenue of exploration involves substituting the contact metal at the metal–semiconductor interface of field-effect transistors with semiconducting layers to introduce additional functionalities to the devices. Here, a scalable approach for fabricating metal–oxide–semiconductor (channel)–semiconductor (interfacial layer) field-effect transistors is proposed by utilizing solution-processed semiconductors, specifically semiconducting single-walled carbon nanotubes and molybdenum disulfide, as the channel and interfacial semiconducting layers, respectively. The work function of the interfacial MoS2 is modulated by controlling the sulfur vacancy concentration through chemical treatment, which results in distinctive energy band alignments within a single device configuration. The resulting band alignments lead to multiple functionalities, including multivalued transistor characteristics and multibit nonvolatile memory (NVM) behavior. Moreover, leveraging the stable NVM properties, we demonstrate artificial synaptic devices with 88.9% accuracy of MNIST image recognition.
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title Defect-Engineered Semiconducting van der Waals Thin Film at Metal–Semiconductor Interface of Field-Effect Transistors
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