• Title/Summary/Keyword: Van der Waals heterostructure

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Silicene on Other Two-dimensional Materials: Formation of Heterostructure

  • Kim, Jung Hwa;Lee, Zonghoon
    • Applied Microscopy
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    • v.44 no.4
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    • pp.123-132
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    • 2014
  • Silicene is one of the most interesting two-dimensional materials, because of not only the extraordinary properties similar to graphene, but also easy compatibility with existing silicon-based devices. However, non-existing graphitic-like structure on silicon and unstable free-standing silicene structure leads to difficulty in commercialization of this material. Therefore, substrates are essential for silicene, which affects various properties of silicene and supporting unstable structure. For maintaining outstanding properties of silicene, van der Waals bonding between silicene and substrate is essential because strong interaction, such as silicene with metal, breaks the band structure of silicene. Therefore, we review the stability of silicene on other two-dimensional materials for van der Waals bonding. In addition, the properties of silicene are reviewed for silicene-based heterostructure.

Field-effect Transistors Based on a Van der Waals Vertical Heterostructure Using CVD-grown Graphene and MoSe2 (화학기상증착법을 통해 합성된 그래핀 및 MoSe2를 이용한 반데르발스 수직이종접합 전계효과 트랜지스터)

  • Seon Yeon Choi;Eun Bee Ko;Seong Kyun Kwon;Min Hee Kim;Seol Ah Kim;Ga Eun Lee;Min Cheol Choi;Hyun Ho Kim
    • Journal of Adhesion and Interface
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    • v.24 no.3
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    • pp.100-104
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    • 2023
  • Van der Waals heterostructures have garnered significant attention in recent research due to their excellent electronic characteristics arising from the absence of dangling bonds and the exclusive reliance on Van der Waals forces for interlayer coupling. However, most studies have been confined to fundamental research employing the Scotch tape (mechanical exfoliation) method. We fabricated Van der Waals vertical heterojunction transistors to advance this field using materials exclusively grown via chemical vapor deposition (CVD). CVDgrown graphene was patterned through photolithography to serve as electrodes, while CVD-grown MoSe2 was employed as the pickup/transfer material, resulting in the realization of Van der Waals heterojunction transistors with interlayer charge transfer effects. The electrical characteristics of the fabricated devices were thoroughly examined. Additionally, we observed variations in the transistor's performance based on the presence of defects in MoSe2 layer.

Chemical Vapor Deposition of High-Quality MoSe2 Monolayer and Its Application to van der Waals Heterostructure-Based High-Performance Field-Effect Transistors (화학기상증착법을 통한 고품질 단층 MoSe2합성 및 반데르발스 수직이종 접합 구조 기반 고성능 트랜지스터 제작)

  • Si Heon Lim;Sun Woo Kim;Seon Yeon Choi;Hyun Ho Kim
    • Journal of Adhesion and Interface
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    • v.24 no.1
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    • pp.36-40
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    • 2023
  • A van der Waals material refers to a material having a two-dimensional layered structure composed of van der Waals bonds with weak interlayer bonding. The research based on heterojunction structures using such van der Waals two-dimensional materials has been steadily studied since the discovery of graphene. Herein, this paper reports a van der Waals heterojunction -based field-effect transistor device based on monolayer single crystalline MoSe2 grown by atmospheric pressure chemical vapor deposition. We found that MoSe2 grown under optimized process conditions did not have atomic-level defects and the transistor devices incorporating MoSe2 also showed excellent characteristics.

Two-dimensional heterostructures for All-2D Electronics

  • Lee, Gwan-Hyeong
    • Proceedings of the Korean Vacuum Society Conference
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    • 2016.02a
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    • pp.100-100
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    • 2016
  • Among various two-dimensional (2D) materials, 2D semiconductors and insulators have attracted a great deal of interest from nanoscience community beyond graphene, due to their attractive and unique properties. Such excellent characteristics have triggered highly active researches on 2D materials, such as hexagonal boron nitride (hBN), molybdenum disulfide (MoS2), and tungsten diselenide (WSe2). New physics observed in 2D semiconductors allow for development of new-concept devices. Especially, these emerging 2D materials are promising candidates for flexible and transparent electronics. Recently, van der Waals heterostructures (vdWH) have been achieved by putting these 2D materials onto another, in the similar way to build Lego blocks. This enables us to investigate intrinsic physical properties of atomically-sharp heterostructure interfaces and fabricate high performance optoelectronic devices for advanced applications. In this talk, fundamental properties of various 2D materials will be introduced, including growth technique and influence of defects on properties of 2D materials. We also fabricate high performance electronic/optoelectronic devices of vdWH, such as transistors, memories, and solar cells. The device platform based on van der Waals heterostructures show huge improvement of devices performance, high stability and transparency/flexibility due to unique properties of 2D materials and ultra-sharp heterointerfaces. Our work paves a new way toward future advanced electronics based on 2D materials.

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Integer and fractional quantum Hall effect in graphene heterostructure

  • Youngwook Kim
    • Progress in Superconductivity and Cryogenics
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    • v.25 no.1
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    • pp.1-5
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    • 2023
  • The study of two-dimensional electron systems with extraordinarily low levels of disorder was, for a long time, the exclusive privilege of the epitaxial thin film research community. However, the successful isolation of graphene by mechanical exfoliation has truly disrupted this field. Furthermore, the assembly of heterostructures consisting of several layers of different 2D materials in arbitrary order by exploiting van der Waals forces has been a game-changer in the field of low-dimensional physics. This technique can be generalized to the large class of strictly 2D materials and offers unprecedented parameters to play with in order to tune electronic and other properties. It has led to a paradigm shift in the field of 2D condensed matter physics with bright prospects. In this review article, we discuss three device fabrication techniques towards high mobility devices: suspended structures, dry transfer, and pick-up transfer methods. We also address state-of-the-art device structures, which are fabricated by the van der Waals pick-up transfer method. Finally, we briefly introduce correlated ground states in the fractional quantum Hall regime.

Reliable charge retention in nonvolatile memories with van der Waals heterostructures

  • Qiu, Dongri;Kim, Eun Kyu
    • Proceedings of the Korean Vacuum Society Conference
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    • 2016.02a
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    • pp.282.1-282.1
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    • 2016
  • The remarkable physical properties of two-dimensional (2D) semiconducting materials such as molybdenum disulfide ($MoS_2$) and tungsten disulfide ($WS_2$) etc. have attracted considerable attentions for future high-performance electronic and optoelectronic devices. The ongoing studies of $MoS_2$ based nonvolatile memories have been demonstrated by worldwide researchers. The opening hysteresis in transfer characteristics have been revealed by different charge confining layer, for instance, few-layer graphene, $MoS_2$, metallic nanocrystal, hafnium oxide, and guanine. However, limited works built their nonvolatile memories using entirely of assembled 2D crystals. This is important in aspect view of large-scale manufacture and vertical integration for future memory device engineering. We report $WS_2$ based nonvolatile memories utilizing functional van der Waals heterostructure in which multi-layered graphene is encapsulated between $SiO_2$ and hexagonal boron nitride (hBN). We experimentally observed that, large memory window (20 V) allows to reveal high on-/off-state ratio (>$10^3$). Moreover, the devices manifest perfect retention of 13% charge loss after 10 years due to large graphene/hBN barrier height. Interestingly, the performance of our memories is drastically better than ever published work related to $MoS_2$ and black phosphorus flash memory technology.

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