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) × 104 S/m is consistent with that reported for bulk PtSe2, confirming that 3-nm-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.

Quantitative Scanning Microwave Microscopy of Few-layer Platinum Diselenide / Wang, X.; Xiong, K.; Li, L.; Hwang, J. C. M.; Jin, X.; Fabi, G.; Farina, M.; Hartwig, O.; Prechtl, M.; Dusberg, G. S.; Goritz, A.; Wietstruck, M.; Kaynak, M.. - (2021), pp. 987-990. (Intervento presentato al convegno 50th European Microwave Conference, EuMC 2020 tenutosi a nld nel 2021) [10.23919/EuMC48046.2021.9338192].

Quantitative Scanning Microwave Microscopy of Few-layer Platinum Diselenide

Fabi G.;Farina M.;
2021-01-01

Abstract

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) × 104 S/m is consistent with that reported for bulk PtSe2, confirming that 3-nm-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.
2021
978-2-87487-059-0
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11566/288364
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