Study of reaction-diffusion controlled mass transport in stopped-flow fluidics for spatiotemporal multiplexing

Tintelott, Marcel; Gharpure, Pradnya; Coffinier, Yannick; Vu, Xuan Thang; Vlandas, Alexis; Ingebrandt, Sven; Pachauri, Vivek

doi:10.1063/5.0146585

Physics of Fluids

2023

DOI: 10.1063/5.0146585

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Study of reaction-diffusion controlled mass transport in stopped-flow fluidics for spatiotemporal multiplexing

Marcel Tintelott

Pradnya Gharpure

Yannick Coffinier

et al.

Abstract: Integration of biochemical reaction networks (BRNs) with biosensor platforms has emerged as a technological niche overcoming challenges related to the loss of sensitivity and selectivity in biological media. Optimal operation of BRNs in microfluidics requires control over reaction-diffusion dominated mass transport, heavily influenced by fluidic parameters. In this work, we study and design an on-chip platform combining a programable unique molecular amplification as BRNs with nanoscale biologically sensitive … Show more

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Reaction characteristics of non-Newtonian species in a microreactor: The role of electroosmotic vortices

Mehta,

Kakati,

Rahman

et al. 2023

Physics of Fluids

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With a focus on biochemical applications and utilizing relevant physical properties, the current study numerically analyzes the impact of electroosmotic vortex and fluid rheology on the chemical reaction characteristics of species. This is achieved by installing integrated positively charged patches on the extended region of the microreactor with three inlets for injecting the reactants and generating the electroosmotic vortex. In order to produce species “C” in the extended region of the microreactor, it is presumed that reactant species “A” is injected through the upper and lower inlets and reactant species “B” is injected via the intermediate inlet. To solve the associated transport equations with appropriate boundary conditions, a thorough theoretical framework is developed. The results show that the ability of the reactant species to react is boosted when vortices form in the microreactor, increasing the convective mixing strength for reactant species. Furthermore, the fluid rheology significantly affects the reaction characteristics, which is a noteworthy finding. For fluids exhibiting a higher shear-thinning nature, the average concentration of the produced species follows an increasing–decreasing trend with the Carreau number. Additionally, it becomes apparent that the influence of the Damkohler number on the average generated species concentration is negligible at lower Carreau numbers, but it increases with the Damkohler number at higher Carreau numbers. The study also reveals that both rheological and chemical parameters have a substantial impact on the flow rate of product species. Overall, the findings of this investigation provide valuable insights for the development of technologically advanced electroosmotic microreactor capable of effectively generating the intended product species.

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Reaction characteristics of non-Newtonian species in a microreactor: The role of electroosmotic vortices

Mehta,

Kakati,

Rahman

et al. 2023

Physics of Fluids

View full text Add to dashboard Cite

show abstract

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Study of reaction-diffusion controlled mass transport in stopped-flow fluidics for spatiotemporal multiplexing

Cited by 1 publication

References 49 publications

Reaction characteristics of non-Newtonian species in a microreactor: The role of electroosmotic vortices

Reaction characteristics of non-Newtonian species in a microreactor: The role of electroosmotic vortices

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