High-precision interferometric measurement of slow and fast temperature changes in static fluid and convective flow

TL;DR

This paper demonstrates a high-precision, non-intrusive interferometric method for measuring minute temperature changes in water, capable of capturing dynamic fluid patterns in real-time, validated by complementary techniques.

Contribution

It introduces a novel application of Michelson interferometry for real-time, high-precision temperature measurement in fluid flows, revealing detailed fluid dynamical features non-invasively.

Findings

Detected asymmetry in thermal plumes not observable with traditional sensors

Achieved measurement precision of a few millikelvin

Validated results with Particle Image Velocimetry and simulations

Abstract

We explore the strengths and limitations of using a standard Michelson interferometer to sample line-of-sight-averaged temperature in water via two experimental setups: slow-varying temperature in static fluid and fast temperature variations in convective flow. The high precision of our measurements (a few mK) is enabled by the fast response time and high sensitivity of the interferometer to minute changes in the refractive index of water caused by temperature variations. These features allow us to detect the signature of fine fluid dynamical patterns in convective flow in a fully non-intrusive manner. For example, we are able to observe an asymmetry in the rising thermal plume (i.e. an asynchronous arrival of two counter-rotating vortices at the measurement location), which is not possible to resolve with more traditional (and invasive) techniques, such as RTD (Resistance Temperature Detector) sensors. These findings, and the overall reliability of our method, are further corroborated by means of Particle Image Velocimetry and Large Eddy Simulations. While this method presents inherent limitations (mainly stemming from the line-of-sight-averaged nature of its results), its non-intrusiveness and robustness, along with the ability to readily yield real-time, highly accurate measurements, render this technique very attractive for a wide range of applications in experimental fluid dynamics.