Residence time distributions for in-line chaotic mixers

Nelson Poumaere; Benoît Pier; Florence Raynal

doi:10.1103/PhysRevE.106.015107

Residence time distributions for in-line chaotic mixers

Nelson Poumaere, Benoît Pier, Florence Raynal^*

^*Corresponding author for this work

School of Earth & Environmental Sciences

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

Abstract

We investigate the distributions of residence time for in-line chaotic mixers; in particular, we consider the Kenics, the F-mixer, and the multilevel laminating mixer and also a synthetic model that mimics their behavior and allows exact mathematical calculations. We show that whatever the number of elements of mixer involved, the distribution possesses a 𝑡−3 tail, so that its shape is always far from Gaussian. This 𝑡−3 tail also invalidates the use of second-order moment and variance. As a measure for the width of the distribution, we consider the mean absolute deviation and show that, unlike the standard deviation, it converges in the limit of large sample size. Finally, we analyze the performances of the different in-line mixers from the residence-time point of view when varying the number of elements and the shape of the cross section.

Original language	English
Pages (from-to)	015107
Journal	Physical Review E
Volume	106
DOIs	https://doi.org/10.1103/PhysRevE.106.015107
Publication status	Published - 19 Jul 2022

Keywords

Chaotic advection
Engineering
Microfluids

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title = "Residence time distributions for in-line chaotic mixers",

abstract = "We investigate the distributions of residence time for in-line chaotic mixers; in particular, we consider the Kenics, the F-mixer, and the multilevel laminating mixer and also a synthetic model that mimics their behavior and allows exact mathematical calculations. We show that whatever the number of elements of mixer involved, the distribution possesses a 𝑡−3 tail, so that its shape is always far from Gaussian. This 𝑡−3 tail also invalidates the use of second-order moment and variance. As a measure for the width of the distribution, we consider the mean absolute deviation and show that, unlike the standard deviation, it converges in the limit of large sample size. Finally, we analyze the performances of the different in-line mixers from the residence-time point of view when varying the number of elements and the shape of the cross section.",

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T1 - Residence time distributions for in-line chaotic mixers

AU - Poumaere, Nelson

AU - Pier, Benoît

AU - Raynal, Florence

PY - 2022/7/19

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N2 - We investigate the distributions of residence time for in-line chaotic mixers; in particular, we consider the Kenics, the F-mixer, and the multilevel laminating mixer and also a synthetic model that mimics their behavior and allows exact mathematical calculations. We show that whatever the number of elements of mixer involved, the distribution possesses a 𝑡−3 tail, so that its shape is always far from Gaussian. This 𝑡−3 tail also invalidates the use of second-order moment and variance. As a measure for the width of the distribution, we consider the mean absolute deviation and show that, unlike the standard deviation, it converges in the limit of large sample size. Finally, we analyze the performances of the different in-line mixers from the residence-time point of view when varying the number of elements and the shape of the cross section.

AB - We investigate the distributions of residence time for in-line chaotic mixers; in particular, we consider the Kenics, the F-mixer, and the multilevel laminating mixer and also a synthetic model that mimics their behavior and allows exact mathematical calculations. We show that whatever the number of elements of mixer involved, the distribution possesses a 𝑡−3 tail, so that its shape is always far from Gaussian. This 𝑡−3 tail also invalidates the use of second-order moment and variance. As a measure for the width of the distribution, we consider the mean absolute deviation and show that, unlike the standard deviation, it converges in the limit of large sample size. Finally, we analyze the performances of the different in-line mixers from the residence-time point of view when varying the number of elements and the shape of the cross section.

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KW - Microfluids

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SN - 1539-3755

VL - 106

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JO - Physical Review E

JF - Physical Review E

ER -

Residence time distributions for in-line chaotic mixers

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