Dynamics of light-induced thermomechanical mirror deformations in high-finesse Fabry&#x2013;Perot microresonators

Kumarasiri Konthasinghe; Juan Gomez Velez; Manoj Peiris; Yamil Nieves; Luisa T. M. Profeta; Andreas Muller

doi:10.1364/JOSAB.35.000372

Journal of the Optical Society of America B
Vol. 35,
Issue 2,
pp. 372-379
(2018)
•https://doi.org/10.1364/JOSAB.35.000372

Dynamics of light-induced thermomechanical mirror deformations in high-finesse Fabry–Perot microresonators

Kumarasiri Konthasinghe, Juan Gomez Velez, Manoj Peiris, Yamil Nieves, Luisa T. M. Profeta, and Andreas Muller

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Kumarasiri Konthasinghe, Juan Gomez Velez, Manoj Peiris, Yamil Nieves, Luisa T. M. Profeta, and Andreas Muller, "Dynamics of light-induced thermomechanical mirror deformations in high-finesse Fabry–Perot microresonators," J. Opt. Soc. Am. B 35, 372-379 (2018)

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- Instrumentation, Measurement, and Metrology
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About this Article
History
- Original Manuscript: October 4, 2017
- Revised Manuscript: December 21, 2017
- Manuscript Accepted: December 22, 2017
- Published: January 26, 2018

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Abstract

Light recirculating inside an optical resonator can spontaneously trigger persistent cyclical thermomechanical mirror deformations. We have observed and characterized the dynamics of such deformations in high-finesse Fabry–Perot microcavities built following three distinct designs. The designs differed in form factor and confinement geometry, incorporating either (A) two nominally planar bulk mirrors, (B) one planar and one microconcave bulk mirror, or (C) one microconcave bulk mirror and one microconcave mirror at the tip of an optical fiber. For all cases, the cavity transmission exhibited bistability and high-frequency ( $\sim MHz$ ), high-amplitude pulsations for input powers greater than $\approx 10 mW$ at a cavity finesse of $\approx 30000$ . A theoretical analysis reveals that these pulsations are the result of the competition between photothermal expansion and photothermal refraction in the mirror coatings that induces “slow-fast” dynamics. We model these dynamics for the three different cavities and show that their varying duty cycles and periods are consistent with light-induced heating and heat dissipation conforming to the cavity mode spot size and the mechanical mirror support structure.

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Cavity	Geometry	Cavity Length $L$ (μm)^a	Mode Spot Size $w_{0}$ (μm)^b	Cavity Finesse^c	Center Wavelength $λ$ (nm)	Nominal Mirror Curvature (μm)	Peak Circulating Power $α P_{in}$ (W)
A	Planar	4	30	150 000	815	$\infty / \infty$	40
B	Plano-concave	10	2.2	60 000	920	$\infty / 50$	50
C	Concave	10	2.2	60 000	920	50/50	15

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Journal of the Optical Society of America B