Amplifying thermal conduction calibre of nanocolloids employing induced electrophoresis

TL;DR

This paper demonstrates that applying electrophoresis to nanocolloids significantly enhances their heat conduction capabilities, with dielectric properties and surfactants playing key roles in optimizing thermal performance.

Contribution

It introduces a novel experimental approach to amplify nanocolloid heat transfer via electrophoresis, supported by a mathematical model predicting performance enhancement.

Findings

Electrophoresis increases thermal conduction beyond Brownian and thermophoretic effects.

Dielectric properties of particles are crucial for electrophoretic heat transfer enhancement.

Surfactants improve colloidal stability and further boost electrophoretic heat transfer.

Abstract

Electrophoresis has been shown as a novel methodology to enhance heat conduction capabilities of nanocolloidal dispersions. A thoroughly designed experimental system has been envisaged to solely probe heat conduction across nanofluids by specifically eliminating the buoyancy driven convective component. Electric field is applied across the test specimen in order to induce electrophoresis in conjunction with the existing thermal gradient. It is observed that the electrophoretic drift of the nanoparticles acts as an additional thermal transport drift mechanism over and above the already existent Brownian diffusion and thermophoresis dominated thermal conduction. A scaling analysis of the thermophoretic and electrophoretic velocities from classical Huckel-Smoluchowski formalism is able to mathematically predict the thermal performance enhancement due to electrophoresis. It is also inferred that the dielectric characteristics of the particle material is the major determining component of the electrophoretic amplification of heat transfer. Influence of surfactants has also been probed into and it is observed that enhancing the stability via surface charge modulation can in fact enhance the electrophoretic drift, thereby enhancing heat transfer calibre. Also, surfactants ensure colloidal stability as well as chemical gradient induced recirculation, thus ensuring colloidal phase equilibrium and low hysteresis in spite of the directional drift in presence of electric field forcing. The findings may have potential implications in enhanced and tunable thermal management of micro nanoscale devices.