| Literature DB >> 35957105 |
Myrron Albert Callera Aguila1,2,3, Joshoua Condicion Esmenda1,2,3, Jyh-Yang Wang3, Yen-Chun Chen3, Teik-Hui Lee3, Chi-Yuan Yang3, Kung-Hsuan Lin3, Kuei-Shu Chang-Liao1, Sergey Kafanov4, Yuri A Pashkin4, Chii-Dong Chen3.
Abstract
Nanomechanical resonators made from van der Waals materials (vdW NMRs) provide a new tool for sensing absorbed laser power. The photothermal response of vdW NMRs, quantified from the resonant frequency shifts induced by optical absorption, is enhanced when incorporated in a Fabry-Pérot (FP) interferometer. Along with the enhancement comes the dependence of the photothermal response on NMR displacement, which lacks investigation. Here, we address the knowledge gap by studying electromotively driven niobium diselenide drumheads fabricated on highly reflective substrates. We use a FP-mediated absorptive heating model to explain the measured variations of the photothermal response. The model predicts a higher magnitude and tuning range of photothermal responses on few-layer and monolayer NbSe2 drumheads, which outperform other clamped vdW drum-type NMRs at a laser wavelength of 532 nm. Further analysis of the model shows that both the magnitude and tuning range of NbSe2 drumheads scale with thickness, establishing a displacement-based framework for building bolometers using FP-mediated vdW NMRs.Entities:
Keywords: Fabry–Pérot interferometry; NbSe2 drumheads; absorptive heating; nanomechanical resonators; photothermal response; static displacement; van der Waals materials
Year: 2022 PMID: 35957105 PMCID: PMC9370576 DOI: 10.3390/nano12152675
Source DB: PubMed Journal: Nanomaterials (Basel) ISSN: 2079-4991 Impact factor: 5.719