Feasibility study of a novel technique for measurement of liquid thermal conductivity with a micro-beam sensor

Hiroshi Takamatsu; Kyosuke Inada; Satoru Uchida; Koji Takahashi; Motoo Fujii

doi:10.1007/s10765-009-0700-5

Feasibility study of a novel technique for measurement of liquid thermal conductivity with a micro-beam sensor

Hiroshi Takamatsu, Kyosuke Inada, Satoru Uchida, Koji Takahashi, Motoo Fujii

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

A new method was proposed to measure the thermal conductivity of liquids with infinitesimal samples, which are much smaller than those required in conventional methods. The method utilizes a micro-beam-type MEMS sensor fabricated across a trench on a silicon substrate. Numerical analysis of heat conduction within and around a uniformly heated sensor showed that the temperature of a 10 μm long sensor reached a steady state within approximately 0.1 ms, after the start of heating. It was also revealed that the average temperature of the sensor at the steady state was higher in liquids with lower thermal conductivity. These results demonstrate a new idea of measuring the thermal conductivity of liquids within an extremely short time at a steady state before the onset of natural convection.

Original language	English
Pages (from-to)	888-899
Number of pages	12
Journal	International Journal of Thermophysics
Volume	31
Issue number	4-5
DOIs	https://doi.org/10.1007/s10765-009-0700-5
Publication status	Published - May 2010

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1007/s10765-009-0700-5

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abstract = "A new method was proposed to measure the thermal conductivity of liquids with infinitesimal samples, which are much smaller than those required in conventional methods. The method utilizes a micro-beam-type MEMS sensor fabricated across a trench on a silicon substrate. Numerical analysis of heat conduction within and around a uniformly heated sensor showed that the temperature of a 10 μm long sensor reached a steady state within approximately 0.1 ms, after the start of heating. It was also revealed that the average temperature of the sensor at the steady state was higher in liquids with lower thermal conductivity. These results demonstrate a new idea of measuring the thermal conductivity of liquids within an extremely short time at a steady state before the onset of natural convection.",

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AU - Takamatsu, Hiroshi

AU - Inada, Kyosuke

AU - Uchida, Satoru

AU - Takahashi, Koji

AU - Fujii, Motoo

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Feasibility study of a novel technique for measurement of liquid thermal conductivity with a micro-beam sensor

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