2011
DOI: 10.1063/1.3631342
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Optical method for measuring thermal accommodation coefficients using a whispering-gallery microresonator

Abstract: A novel optical method has been developed for the measurement of thermal accommodation coefficients in the temperature-jump regime. The temperature dependence of the resonant frequency of a fused-silica microresonator's whispering-gallery mode is used to measure the rate at which the microresonator comes into thermal equilibrium with the ambient gas. The thermal relaxation time is related to the thermal conductivity of the gas under some simplifying assumptions and measuring this time as a function of gas pres… Show more

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Cited by 36 publications
(38 citation statements)
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“…The relationship between the gas temperatures and the surface temperature of the sphere is given by a material constant, the accommodation coefficient α = T em −T imp Tsur−T imp . The accommodation coefficient for silica is known 19 and close to 0.777 for moderate surface temperatures around 300 K. This allows us to infer the surface temperature of the nanospheres, Tsur = 294 K + T em −294 K 0.777…”
mentioning
confidence: 90%
“…The relationship between the gas temperatures and the surface temperature of the sphere is given by a material constant, the accommodation coefficient α = T em −T imp Tsur−T imp . The accommodation coefficient for silica is known 19 and close to 0.777 for moderate surface temperatures around 300 K. This allows us to infer the surface temperature of the nanospheres, Tsur = 294 K + T em −294 K 0.777…”
mentioning
confidence: 90%
“…In particular, a gas possesses a characteristic thermal conductivity, which can give rise to differing thermal responses. For example, the equilibrium temperature in a thermometry type setup [270] or the thermal relaxation time can be monitored [271], which are both critically dependent on the thermal conductivity of the surrounding gas. Similarly turn-on transients can also be used to discriminate different gases through their thermal conductivity [272].…”
Section: Sensingmentioning
confidence: 99%
“…where p is the pressure of gas, k B the Boltzmann constant, a is the thermal accommodation coefficient which accounts for the interaction between the gas molecule and the two surfaces at temperatures T 1 = 300 K and T 2 = 0 K, M is the mass of a gas molecule (≈ 4.8 × 10 − 26 kg for air), and the functions 1 T ′ and 2 T ′ are given by The value of a can be determined experimentally and for most surfaces lies in the range 0.75-0.9 [22,23]. Here, we assume a value a = 0.8 for our calculations.…”
Section: Heat Transfermentioning
confidence: 99%