Numerical Study of Joule Heating Effects on Microfluidics Device Reliability in Electrode Based Devices

Overview

Journal Materials (Basel)

Publisher MDPI

Date 2021 Oct 13

PMID 34640216

Citations 2

Authors

Caffiyar Mohammed Yousuff

Vineet Tirth

Mohamed Zackria Ansar Babu Irshad

Kashif Irshad

Ali Algahtani

Saiful Islam

Affiliations

Soon will be listed here.

Abstract

In electrode-based microfluidic devices, micro channels having narrow cross sections generate undesirable temperature inside the microfluidic device causing strong thermal distribution (joule heating) that eventually leads to device damage or cell loss. In this work, we investigate the effects of joule heating due to different electrode configuration and found that, electrodes with triangular arrangements produce less heating effect even at applied potential of 30 V, without compromising the performance of the device and separation efficiency. However, certain electrode materials have low thermal gradients but erode the channel quickly thereby affecting the reliability of the device. Our simulation also predicts optimal medium conductivity (10 mS/m with 10 V) for cells to survive inside the channel until they are selectively isolated into the collection outlet. Our investigations will aid the researchers in the designing of efficient and reliable microfluidic devices to overcome joule heating inside the microchannels.

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