Abstract
Particle image velocimetry (PIV) is a well-established tool to collect high-resolution velocity and turbulence data in the laboratory, in both air and water. Laboratory experiments are often performed under conditions of constant temperature or salinity or in flows with only small gradients of these properties. At larger temperature or salinity variations, the changes in the index of refraction of water or air due to turbulent microstructure can lead to so-called optical turbulence. We observed a marked influence of optical turbulence on particle imaging in PIV. The effect of index of refraction variations on PIV has been described in air for high Mach number flows, but in such cases the distortion is directional. No such effect has previously been reported for conditions of isotropic optical turbulence in water. We investigated the effect of optical turbulence on PIV imaging in a large Rayleigh-Bénard tank for various path lengths and turbulence strengths. The results show that optical turbulence can significantly affect PIV measurements. Depending on the strength of the optical turbulence and path length, the impact can be mitigated in post-processing, which may reduce noise and recover the mean velocity signal, but leads to the loss of the high-frequency turbulence signal.
Highlights
Optical turbulence refers to the impact of index of refraction variations on optical signal transmission[1]
We observed a marked influence of optical turbulence on particle imaging in Particle image velocimetry (PIV) and investigated this effect for various path lengths (0.5 m to 2 m) and optical turbulence strengths
The results indicate that optical turbulence can affect PIV measurements and the impact depends on the strength of the optical turbulence and path length
Summary
Optical turbulence refers to the impact of index of refraction variations on optical signal transmission[1]. The impact from density variations is expected to be pronounced under ice, an emerging area of interest for wave and turbulence studies of wide-ranging importance for local and global forecasting models, with numerous projected applications for PIV measurements. With such marked effects of density variations on optical imaging, the impact on PIV imaging and on inferred velocity fields warrants a thorough investigation. Note that a Rytov variance σ2 > 0.3 is considered a transition from the low to moderate optical turbulence regime
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