Universal length dependence of tensile stress in nanomechanical string resonators
Maximilian B\"uckle, Yannick S. Kla{\ss}, Felix B. N\"agele, R\'emy, Braive, Eva M. Weig
TL;DR
This study reveals a universal length-dependent tensile stress in nanomechanical string resonators across different materials, supported by an elastic model, which could enable stress-based quality factor optimization.
Contribution
It demonstrates a material-independent length dependence of tensile stress in nanomechanical resonators and introduces a simple elastic model to explain this phenomenon.
Findings
Tensile stress increases by ~50% in shorter resonators.
The length dependence is material-independent across four different materials.
The elastic model accurately predicts the observed stress behavior.
Abstract
We investigate the tensile stress in freely suspended nanomechanical string resonators, and observe a material-independent dependence on the resonator length. We compare strongly stressed sting resonators fabricated from four different material systems based on amorphous silicon nitride, crystalline silicon carbide as well as crystalline indium gallium phosphide. The tensile stress is found to increase by approximately 50% for shorter resonators. We establish a simple elastic model to describe the observed length dependence of the tensile stress. The model accurately describes our experimental data. This opens a perspective for stress-engineering the mechanical quality factor of nanomechanical string resonators.
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