少层二硫化铪晶体管。

Few-layer HfS2 transistors.

作者信息

Kanazawa Toru, Amemiya Tomohiro, Ishikawa Atsushi, Upadhyaya Vikrant, Tsuruta Kenji, Tanaka Takuo, Miyamoto Yasuyuki

机构信息

Department of Physical Electronics, Tokyo Institute of Technology, 152-8552 Japan.

Quantum Nano Electronics Research Center, Tokyo Institute of Technology, 152-8552 Japan.

出版信息

Sci Rep. 2016 Mar 1;6:22277. doi: 10.1038/srep22277.

DOI:10.1038/srep22277

PMID:26926098

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4772098/

Abstract

HfS2 is the novel transition metal dichalcogenide, which has not been experimentally investigated as the material for electron devices. As per the theoretical calculations, HfS2 has the potential for well-balanced mobility (1,800 cm(2)/V·s) and bandgap (1.2 eV) and hence it can be a good candidate for realizing low-power devices. In this paper, the fundamental properties of few-layer HfS2 flakes were experimentally evaluated. Micromechanical exfoliation using scotch tape extracted atomically thin HfS2 flakes with varying colour contrasts associated with the number of layers and resonant Raman peaks. We demonstrated the I-V characteristics of the back-gated few-layer (3.8 nm) HfS2 transistor with the robust current saturation. The on/off ratio was more than 10(4) and the maximum drain current of 0.2 μA/μm was observed. Moreover, using the electric double-layer gate structure with LiClO4:PEO electrolyte, the drain current of the HfS2 transistor significantly increased to 0.75 mA/μm and the mobility was estimated to be 45 cm(2)/V·s at least. This improved current seemed to indicate superior intrinsic properties of HfS2. These results provides the basic information for the experimental researches of electron devices based on HfS2.

摘要

HfS2是一种新型的过渡金属二硫属化物，尚未作为电子器件材料进行实验研究。根据理论计算，HfS2具有平衡良好的迁移率（1800 cm²/V·s）和带隙（1.2 eV），因此它可能是实现低功耗器件的理想候选材料。在本文中，对少层HfS2薄片的基本特性进行了实验评估。使用透明胶带进行微机械剥离，得到了具有与层数和共振拉曼峰相关的不同颜色对比度的原子级薄HfS2薄片。我们展示了具有稳健电流饱和特性的背栅少层（3.8 nm）HfS2晶体管的I-V特性。开/关比超过10⁴，观察到的最大漏极电流为0.2 μA/μm。此外，使用含LiClO4:PEO电解质的双电层栅极结构，HfS2晶体管的漏极电流显著增加到0.75 mA/μm，迁移率估计至少为45 cm²/V·s。这种电流的改善似乎表明HfS2具有优异的本征特性。这些结果为基于HfS2的电子器件的实验研究提供了基本信息。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/38d4/4772098/231af608d519/srep22277-f1.jpg

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少层二硫化铪晶体管。

Few-layer HfS2 transistors.

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