Silicon resonators are widely used in a large class of applications including sensing and actuation, signal processing and energy harvesting. Very often, the application for which these sensors are designed requires the deposition of thin films or coatings, in order to modify the optical coupling, the electrical conductivity or other physical-chemical properties of the device. Invariably coatings degrade the quality factor (Q) of resonance by increasing the amount of energy dissipated during vibration. Generally this is an unwanted effect. In fact, developing strategies for controlling damping due to film deposition is vital for the design of high-performance resonators requiring low energy losses. In this paper, we present the results of our strategy for damping control applied to a class of high-Q silicon resonators used for the investigation of thermal noise statistical properties in non-thermodynamic equilibrium both at room temperature and cryogenic temperatures.

Low loss single-crystal silicon resonators for the investigation of thermal noise statistical properties

Serra, Enrico;Bonaldi, Michele;
2015

Abstract

Silicon resonators are widely used in a large class of applications including sensing and actuation, signal processing and energy harvesting. Very often, the application for which these sensors are designed requires the deposition of thin films or coatings, in order to modify the optical coupling, the electrical conductivity or other physical-chemical properties of the device. Invariably coatings degrade the quality factor (Q) of resonance by increasing the amount of energy dissipated during vibration. Generally this is an unwanted effect. In fact, developing strategies for controlling damping due to film deposition is vital for the design of high-performance resonators requiring low energy losses. In this paper, we present the results of our strategy for damping control applied to a class of high-Q silicon resonators used for the investigation of thermal noise statistical properties in non-thermodynamic equilibrium both at room temperature and cryogenic temperatures.
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Utilizza questo identificativo per citare o creare un link a questo documento: http://hdl.handle.net/11582/273419
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