HfO 2 /HfS 2 hybrid heterostructure fabricated via controllable chemical conversion of two-dimensional HfS 2

While preparing uniform dielectric layers on two-dimensional (2D) materials is a key device architecture requirement to achieve next-generation 2D devices, conventional deposition or transfer approaches have been so far limited by their high cost, fabrication complexity, and especially poor dielectr...

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Veröffentlicht in:Nanoscale 2018-10, Vol.10 (39), p.18758-18766
Hauptverfasser: Lai, Shen, Byeon, Seongjae, Jang, Sung Kyu, Lee, Juho, Lee, Byoung Hun, Park, Jin-Hong, Kim, Yong-Hoon, Lee, Sungjoo
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container_end_page 18766
container_issue 39
container_start_page 18758
container_title Nanoscale
container_volume 10
creator Lai, Shen
Byeon, Seongjae
Jang, Sung Kyu
Lee, Juho
Lee, Byoung Hun
Park, Jin-Hong
Kim, Yong-Hoon
Lee, Sungjoo
description While preparing uniform dielectric layers on two-dimensional (2D) materials is a key device architecture requirement to achieve next-generation 2D devices, conventional deposition or transfer approaches have been so far limited by their high cost, fabrication complexity, and especially poor dielectric/2D material interface quality. Here, we demonstrate that HfO , a high-K dielectric, can be prepared on the top surface of 2D HfS through plasma oxidation, which results in a heterostructure composed of a 2D van der Waals semiconductor and its insulating native oxide. A highly uniform dielectric layer with a controlled thickness can be prepared; the possibility of unlimited layer-by-layer oxidation further differentiates our work from previous attempts on other 2D semiconducting materials, which exhibit self-limited oxidation up to only a few layers. High resolution transmission electron microscopy was used to show that the converted HfO /HfS hybrid structure is of high quality with an atomically abrupt, impurity- and defect-free interface. Density functional theory calculations show that the unlimited layer-by-layer oxidation occurs because oxygen atoms can barrierlessly penetrate into the HfS surface and the extracted sulfur atoms are absorbed into the oxygen vacancy sites within HfO under O-rich conditions. A top-gated field-effect transistor fabricated with the converted HfO /HfS hybrid structure was found to exhibit a low interface trap density D of 6 × 10 cm eV between the HfS channel and the converted HfO dielectric, and a high on/off current ratio above 10 . Our approach provides a low cost, simple, and ultraclean manufacturing technique for integrating 2D material into device applications.
doi_str_mv 10.1039/C8NR06020G
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title HfO 2 /HfS 2 hybrid heterostructure fabricated via controllable chemical conversion of two-dimensional HfS 2
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