Reaction-diffusion dynamics: Confrontation between theory and experiment in a microfluidic reactor

Charles N. Baroud; Fridolin Okkels; Laure Ménétrier; Patrick Tabeling

doi:10.1103/PhysRevE.67.060104

Reaction-diffusion dynamics: Confrontation between theory and experiment in a microfluidic reactor

Charles N. Baroud
, Fridolin Okkels
, Laure Ménétrier
, Patrick Tabeling

Research output: Contribution to journal › Article › peer-review

Abstract

We confront, quantitatively, the theoretical description of the reaction-diffusion process of a second-order reaction to experiment. The reaction at work is [Formula presented] a fluorescent tracer for calcium. The reactor is a T-shaped microchannel, [Formula presented] deep, [Formula presented] wide, and 2 cm long. The experimental measurements are compared with the two-dimensional numerical simulation of the reaction-diffusion equations. We find good agreement between theory and experiment. From this study, one may propose a method of measurement of various quantities, such as the kinetic rate of the reaction, in conditions yet inaccessible to conventional methods.

Original language	English
Pages (from-to)	4
Number of pages	1
Journal	Physical Review E
Volume	67
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevE.67.060104
Publication status	Published - 1 Jan 2003

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abstract = "We confront, quantitatively, the theoretical description of the reaction-diffusion process of a second-order reaction to experiment. The reaction at work is [Formula presented] a fluorescent tracer for calcium. The reactor is a T-shaped microchannel, [Formula presented] deep, [Formula presented] wide, and 2 cm long. The experimental measurements are compared with the two-dimensional numerical simulation of the reaction-diffusion equations. We find good agreement between theory and experiment. From this study, one may propose a method of measurement of various quantities, such as the kinetic rate of the reaction, in conditions yet inaccessible to conventional methods.",

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AU - Baroud, Charles N.

AU - Okkels, Fridolin

AU - Ménétrier, Laure

AU - Tabeling, Patrick

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Y1 - 2003/1/1

N2 - We confront, quantitatively, the theoretical description of the reaction-diffusion process of a second-order reaction to experiment. The reaction at work is [Formula presented] a fluorescent tracer for calcium. The reactor is a T-shaped microchannel, [Formula presented] deep, [Formula presented] wide, and 2 cm long. The experimental measurements are compared with the two-dimensional numerical simulation of the reaction-diffusion equations. We find good agreement between theory and experiment. From this study, one may propose a method of measurement of various quantities, such as the kinetic rate of the reaction, in conditions yet inaccessible to conventional methods.

AB - We confront, quantitatively, the theoretical description of the reaction-diffusion process of a second-order reaction to experiment. The reaction at work is [Formula presented] a fluorescent tracer for calcium. The reactor is a T-shaped microchannel, [Formula presented] deep, [Formula presented] wide, and 2 cm long. The experimental measurements are compared with the two-dimensional numerical simulation of the reaction-diffusion equations. We find good agreement between theory and experiment. From this study, one may propose a method of measurement of various quantities, such as the kinetic rate of the reaction, in conditions yet inaccessible to conventional methods.

UR - https://www.scopus.com/pages/publications/85022112545

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VL - 67

SP - 4

JO - Physical Review E

JF - Physical Review E

IS - 6

ER -

Reaction-diffusion dynamics: Confrontation between theory and experiment in a microfluidic reactor

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