Thermal vibration of MoS2/Black phosphorus Bi-layered heterostructure
YQ Zhang and LF Wang and JN Jiang, PHYSICA E-LOW-DIMENSIONAL SYSTEMS & NANOSTRUCTURES, 114, 113597 (2019).
DOI: 10.1016/j.physe.2019.113597
Thermal vibration is extremely crucial to nanostructure-based nanoresonators. In this paper, a laminated plate model (LPM) with the van der Waals (vdW) interactions between MoS2 and black phosphorus (BP) taken into consideration is proposed to explore the thermally induced vibration of a MoS2/BP heterostructure. The vdW coefficient between single-layered MoS2 and single-layered BP is calculated. The natural frequencies and the root-mean-squared (RMS) amplitudes of the MoS2/BP heterostructure are obtained from molecular dynamics (MD) simulations and the LPM. The natural frequencies and the RMS amplitudes of the MoS2/BP heterostructure calculated by the LPM and those obtained from the MD simulations coincide well. The LPM has in-phase vibrational modes and anti-phase vibrational modes. The natural frequencies of the in- phase vibrational modes are much lower than the frequencies of the anti- phase vibrational modes of the same order. In the thermal vibration of the MoS2/BP heterostructure, the RMS amplitudes of MoS2 and BP are obviously different. Compared with the natural frequencies and RMS amplitudes of the MoS2/BP heterostructure obtained from the MD simulations, the LPM can provide an accurate prediction of the thermal vibration of the MoS2/BP heterostructure.
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