📝 SummarXiv

Abstract

Microfluidic channels are integral to biomedical technology and process engineering, offering versatility in handling fluids with complex properties, often a combination of viscous and elastic attributes. Despite significant advancements in understanding small-scale fluid-structure interactions, however, experimental insights on the flow of complex fluids in deformable microchannels remain limited. Here, we present controlled experiments using polymer solutions as model viscoelastic fluids to examine the effects of polymer concentration on the elasto-mechanical characteristics of slender cylindrical microchannels. The findings indicate significant differences in fluid-structure interactions between dilute and semi-dilute polymer solutions with varying molecular weights. At higher polymer concentrations, these interactions intensify, leading to reduced pressure drops in high-shear regions and increased pressure drops in low-shear areas, linked to local wall deformation. The increased elasticity of higher concentration solutions further enhances local deformation, disrupts flow, and dissipates energy, resulting in a non-linear rise in pressure drop. This behaviour is aggravated by the solutions increased apparent viscosity due to the entangled polymer network. A theoretical model of flow-induced deformation is also developed, accounting for polymer chain extensibility. These insights highlight the importance of polymer constitution in optimizing the flow characteristics, advancing the development of adaptive microfluidic devices in biological and industrial applications for optimal performance.