Issue 28, 2023

Droplet-on-chip electro-spectroscopy detects the ultra-short relaxation time of a dilute polymer solution

Abstract

We report an electrode-embedded on-chip platform technology for the precise determination of ultra-short (of the order of a few nanoseconds) relaxation times of dilute polymer solutions, by deploying time-alternating electrical voltages. Our methodology delves into the sensitive dependence of the contact line dynamics of a droplet of the polymer solution atop a hydrophobic interface in response to the actuation voltage, resulting in a non-trivial interplay between the time-evolving electrical, capillary, and viscous forces. This culminates into a time-decaying dynamic response that mimics the features of a damped oscillator having its ‘stiffness’ mapped with the polymeric content of the droplet. The observed electro-spreading characteristics of the droplet are thus shown to correlate explicitly with the relaxation time of the polymer solution, drawing analogies with a damped electro-mechanical oscillator. By corroborating well with the reported values of the relaxation times as obtained from more elaborate and sophisticated laboratory set-ups. Our findings provide perspectives for a unique and simple approach towards electrically-modulated on-chip-spectroscopy for deriving ultra-short relaxation times of a broad class of viscoelastic fluids that could not be realized thus far.

Graphical abstract: Droplet-on-chip electro-spectroscopy detects the ultra-short relaxation time of a dilute polymer solution

Article information

Article type
Paper
Submitted
09 May 2023
Accepted
10 Jun 2023
First published
22 Jun 2023

Soft Matter, 2023,19, 5345-5352

Droplet-on-chip electro-spectroscopy detects the ultra-short relaxation time of a dilute polymer solution

R. Roy, J. S. M. Quintero, R. Lakkaraju, P. R. Waghmare and S. Chakraborty, Soft Matter, 2023, 19, 5345 DOI: 10.1039/D3SM00608E

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