Properties of Nanocrystalline Silicon Probed by Optomechanics
Daniel Navarro-Urrios, Martin F. Colombano, Jeremie Maire, Emigdio, Chavez-Angel, Guillermo Arregui, Nestor E. Capuj, Arnaud Devos, Amadeu Griol,, Laurent Bellieres, Alejandro Martinez, Kestutis Grigoras, Teija Hakkinen,, Jaakko Saarilahti, Tapani Makkonen

TL;DR
This study investigates the optical, mechanical, and thermal properties of nanocrystalline silicon using optomechanical nanobeams, revealing how grain size and boundary volume influence dissipation and nonlinear effects for advanced device applications.
Contribution
It demonstrates how annealing temperature controls nanocrystalline silicon properties and their impact on optomechanical performance, highlighting potential for nonlinear device applications.
Findings
High optical quality factor of 13000 in nanocrystalline Si
Mechanical quality factor of 1700 achieved in the nanobeam
Grain boundary volume fraction affects dissipation and nonlinear effects
Abstract
Nanocrystalline materials exhibit properties that can differ substantially from those of their single crystal counterparts. As such, they provide ways to enhance and optimise their functionality for devices and applications. Here we report on the optical, mechanical and thermal properties of nanocrystalline silicon probed by means of optomechanical nanobeams to extract information of the dynamics of optical absorption, mechanical losses, heat generation and dissipation. The optomechanical nanobeams are fabricated using nanocrystalline films prepared by annealing amorphous silicon layers at different temperatures. The resulting crystallite sizes and the stress in the films can be controlled by the annealing temperature and time and, consequently, the properties of the films can be tuned relatively freely, as demonstrated here by means of electron microscopy and Raman scattering. We show…
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