Quantitative Scanning Microwave Microscopy of Few-layer Platinum Diselenide

被引:0
作者
Wang, Xiaopeng [1 ]
Xiong, Kuanchen [1 ]
Li, Lei [1 ]
Hwang, James C. M. [1 ]
Jin, Xin [2 ]
Fabi, Gianluca [3 ]
Farina, Marco [3 ]
Hartwig, Oliver [4 ]
Prechtl, Maximilian [4 ]
Duesberg, Georg S. [4 ]
Goeritz, Alexander [5 ]
Wietstruck, Matthias [5 ]
Kaynak, Mehmet [5 ]
机构
[1] Cornell Univ, Ithaca, NY 14853 USA
[2] Anokiwave Inc, San Diego, CA USA
[3] Marche Polytech Univ, Ancona, Italy
[4] Univ Bundeswehr Munchen, Neubiberg, Germany
[5] IHP Leibniz Inst Innovat Microelect, Frankfurt, Germany
来源
2020 50TH EUROPEAN MICROWAVE CONFERENCE (EUMC) | 2020年
基金
美国国家科学基金会;
关键词
atomic force microscopy; conductivity measurement; microwave imaging; nanomaterials; scanning probe microscopy; PTSE2; EVOLUTION;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
PtSe2 is unique among all 2D materials by having simultaneously sizable bandgap, high carrier mobility, and air stability. Moreover, PtSe2 undergoes a semiconductor-semimetal transition when its thickness increases beyond a few atomic layers, which facilitates low-resistance contact. However, there has been a controversy in how abruptly PtSe2 transitions from a semiconductor to a semimetal. In this work, scanning microwave microscopy was used to quantify the conductivity in two PtSe2 layers 1.5-nm-thick and 3-nm-thick, respectively. The resulted conductivity in 3-nm-thick PtSe2 of (1.7 +/- 0.2) x 10(4) S/m is consistent with that reported for bulk PtSe2, confirming that 3nm-thick PtSe2 is a semimetal. However, although the conductivity in 1.5-nm-thick PtSe2 appears much lower, it is too close to that of TiN to be reliably quantified. To characterize low conductivity in few-layer semiconductors, the signal-to-noise ratio of scanning microwave microscopy needs to be further improved.
引用
收藏
页码:987 / 990
页数:4
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