Dye Attenuation Without Dye: Quantifying Concentration Fields with Short-wave Infrared Imaging

TL;DR

This paper introduces a novel short-wave infrared imaging method to measure liquid concentration and height profiles without dye, enabling accurate tracking of water content in biological and chemical systems with high spatial and temporal resolution.

Contribution

The study demonstrates dye-free concentration measurement using SWIR imaging, expanding fluid dynamics analysis to systems where dye addition is problematic.

Findings

Accurately measures water height down to 0.2mm

Tracks water content evolution in real-time

Validates measurements against analytical mass balance

Abstract

Dye attenuation, or photometric imaging, is an optical technique commonly used in fluid dynamics to measure tracer concentration fields and fluid thicknesses under the assumption that the motion of the dye is representative of the fluid motion and that its presence does not affect the behaviour of the system. However, in some systems, particularly living biological systems or those with strong chemical interactions and reactions, the addition of dye may non-trivially influence the system and may not follow the fluid containing it. To overcome this, we demonstrate how short-wave infrared imaging can be used to measure concentration and height profiles of water and other liquids without the introduction of dye for heights down to 0.2mm with spatial and temporal resolutions of the order of 50 microns per pixel and 120 fps respectively. We showcase the utility of this technique by demonstrating its ability to accurately track the temporal evolution of the total water content of two model systems, namely a water drop spreading on a glass slide and spreading within a hydrogel sheet, validating both against an analytical mass balance. Finally, we discuss how the spectral resolution of the present setup could be increased to the point that concentrations within a multi-component system containing more than one type of liquid could be quantified.