Temperature compensation of optical microresonators using a surface layer with negative thermo-optic coefficient

Ming Han; Anbo Wang

doi:10.1364/OL.32.001800

Optics Letters
Vol. 32,
Issue 13,
pp. 1800-1802
(2007)
•https://doi.org/10.1364/OL.32.001800

Temperature compensation of optical microresonators using a surface layer with negative thermo-optic coefficient

Ming Han and Anbo Wang

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Ming Han and Anbo Wang, "Temperature compensation of optical microresonators using a surface layer with negative thermo-optic coefficient," Opt. Lett. 32, 1800-1802 (2007)

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Abstract

We theoretically investigate the feasibility of using a surface layer with a negative thermo-optic coefficient to compensate the thermal drift of a resonant frequency in an optical microresonator. Taking a fused-silica microsphere as an example, our analysis has shown that the thermal drift of a whisper-gallery mode can be fully compensated by such a surface layer. We analyze and compare the compensation performances by using different materials as the surface layer.

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	$Si O_{2}$	$Ca F_{2}$	PS
$n_{0}$	1.444	1.426	1.49
$d n ∕ d T$ $(\times 10^{- 6} ∕ ° C)$	11.9	$- 11.7$	$- 140$
$α (\times 10^{- 6} ∕ ° C)$	0.55	19.0	70.0

Schott Glass Type	N-FK51	N-PSK53	N-FK5
$n_{0}$	1.486	1.620	1.487
$d n ∕ d T$ $(\times 10^{- 6} ∕ ° C)$	$- 5.70$	$- 2.3$	$- 1.00$
$α (\times 10^{- 6} ∕ ° C)$	13.30	9.4	9.2
$t_{op}$ $(μ m)$	1.204	1.437	NA

	$Si O_{2}$	$Ca F_{2}$	PS
$n_{0}$	1.444	1.426	1.49
$d n ∕ d T$ $(\times 10^{- 6} ∕ ° C)$	11.9	$- 11.7$	$- 140$
$α (\times 10^{- 6} ∕ ° C)$	0.55	19.0	70.0

Schott Glass Type	N-FK51	N-PSK53	N-FK5
$n_{0}$	1.486	1.620	1.487
$d n ∕ d T$ $(\times 10^{- 6} ∕ ° C)$	$- 5.70$	$- 2.3$	$- 1.00$
$α (\times 10^{- 6} ∕ ° C)$	13.30	9.4	9.2
$t_{op}$ $(μ m)$	1.204	1.437	NA

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Optics Letters