Determination of the glass wall effect in optical measurement of temperature in liquid using Mach&#x2013;Zehnder interferometer

Amirhossein Ahadi; M. Ziad Saghir

doi:10.1364/AO.54.000D74

Applied Optics
Vol. 54,
Issue 13,
pp. D74-D81
(2015)
•https://doi.org/10.1364/AO.54.000D74

Determination of the glass wall effect in optical measurement of temperature in liquid using Mach–Zehnder interferometer

Amirhossein Ahadi and M. Ziad Saghir

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Amirhossein Ahadi and M. Ziad Saghir, "Determination of the glass wall effect in optical measurement of temperature in liquid using Mach–Zehnder interferometer," Appl. Opt. 54, D74-D81 (2015)

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Abstract

For optical experiments in which the change of refractive index is monitored, the refractive index of glass would change due to the change of temperature along the walls, and, as a result, the measurements of temperature and concentration would be affected. Because of this, one may use another temperature measurement technique parallel with a Mach–Zehnder interferometer (MZI). For instance, thermocouples or thermometers can be implemented inside the walls to obtain the temperature at the walls and close to the liquid region. The main limitation of this technique is that it provides information at a specific location and not along the walls or inside the liquid zone. On the other hand, the measurement is performed at the location close to the liquid region and not inside the liquid. Thus, in this study, we suggest using the optical method with some modifications that clear up the mentioned limitations. Accordingly, the optical effect of glass in the laser interferometry experiment is first studied. Then, we suggest two experimental methods based on modifications in the experimental setup and the image processing technique of MZI to accurately determine the glass effect and remove this effect from the temperature and concentration measurements. Implementing any of these techniques results in accurate measurement of the temperature and concentration of the liquid in any rectangular cell. Finally, according to the results of this study, it can be claimed that a temperature profile can be obtained precisely using MZI, and the existence of other apparatus to measure the temperature is redundant for the MZI setup. This outcome offers a simpler and more precise measurement of either temperature or concentration profiles of any transparent liquid.

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Symbol	Quantity	Value and SI Unit
$λ_{1}$	Wavelength of the first laser in the SODI apparatus	670 nm
$λ_{2}$	Wavelength of the second laser in the SODI apparatus	935 nm
${(\frac{\partial n}{\partial T})}_{λ 1, liquid}$	Temperature contrast factor of the liquid measured for the first laser	$- 4.812 \times 10^{- 4} K^{- 1}$
${(\frac{\partial n}{\partial T})}_{λ 2, liquid}$	Temperature contrast factor of the liquid measured for the second laser	$- 4.763 \times 10^{- 4} K^{- 1}$
$L_{cell}$	Length of cell	3 cm
$W_{cell}$	Width of liquid region	3 cm
$L_{liquid}$	Length of liquid region	1 cm
$W_{liquid}$	Width of liquid region	1 cm
$H_{liquid}$	Height of liquid region	5 mm

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Applied Optics