Canopy elastic turbulence: Spontaneous formation of waves in beds of slender microposts

Charlotte De Blois; Simon J. Haward; Amy Q. Shen

doi:10.1103/PhysRevFluids.8.023301

Canopy elastic turbulence: Spontaneous formation of waves in beds of slender microposts

Charlotte De Blois, Simon J. Haward, Amy Q. Shen

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

3 Scopus citations

Abstract

In a viscoelastic flow over a microfluidic canopy of polymeric pillars, we report the spontaneous emergence of waves in the form of propagating regions of low flow velocity compared to the surrounding flow. The occurrence of the wave is chaotic and shows characteristics of elastic turbulence. We systematically study the coupling between the low-velocity wave and the microfluidic canopy by combining flow velocimetry experiments and high-speed tracking of the pillars. The waves form an angle ±β with the primary flow direction that depends on the geometry of the pillar array. If the canopy is composed of flexible structures, the passage of a wave deflects the structures locally in a manner reminiscent of the emergence of the Monami waves observed in inertial turbulence over canopies of vegetation. Due to the analogies with classical (inertial) canopy turbulence, we name our observed phenomenon canopy elastic turbulence.

Original language	English (US)
Article number	023301
Journal	Physical Review Fluids
Volume	8
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevFluids.8.023301
State	Published - Feb 2023

ASJC Scopus subject areas

Computational Mechanics
Modeling and Simulation
Fluid Flow and Transfer Processes

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10.1103/PhysRevFluids.8.023301

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title = "Canopy elastic turbulence: Spontaneous formation of waves in beds of slender microposts",

abstract = "In a viscoelastic flow over a microfluidic canopy of polymeric pillars, we report the spontaneous emergence of waves in the form of propagating regions of low flow velocity compared to the surrounding flow. The occurrence of the wave is chaotic and shows characteristics of elastic turbulence. We systematically study the coupling between the low-velocity wave and the microfluidic canopy by combining flow velocimetry experiments and high-speed tracking of the pillars. The waves form an angle ±β with the primary flow direction that depends on the geometry of the pillar array. If the canopy is composed of flexible structures, the passage of a wave deflects the structures locally in a manner reminiscent of the emergence of the Monami waves observed in inertial turbulence over canopies of vegetation. Due to the analogies with classical (inertial) canopy turbulence, we name our observed phenomenon canopy elastic turbulence.",

author = "{De Blois}, Charlotte and Haward, {Simon J.} and Shen, {Amy Q.}",

note = "Funding Information: We gratefully acknowledge the support of the Okinawa Institute of Science and Technology Graduate University (OIST) with subsidy funding from the Cabinet Office, Government of Japan. C.d.B., S.J.H., and A.Q.S. also acknowledge funding from the Japan Society for the Promotion of Science (JSPS, Grants No. 20K14656, No. 21K03884, and No. 20K22403). The authors thank Kazumi Toda-Peters for the experimental help in the use of the LightFab platform and Menouer Saidani and the Nanofab Support Section of OIST for their technical support on the use of the Nanoscribe and the LightFab platform. The authors are also grateful to Shivani Sathish for the acquisition of the SEM images presented in Fig. , and to Eliot Fried, Cameron Hopkins, Daniel Carlson, and Stylianos Varchanis for the stimulating discussions related to the present project. Publisher Copyright: {\textcopyright} 2023 authors. Published by the American Physical Society.",

year = "2023",

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AU - Shen, Amy Q.

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PY - 2023/2

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N2 - In a viscoelastic flow over a microfluidic canopy of polymeric pillars, we report the spontaneous emergence of waves in the form of propagating regions of low flow velocity compared to the surrounding flow. The occurrence of the wave is chaotic and shows characteristics of elastic turbulence. We systematically study the coupling between the low-velocity wave and the microfluidic canopy by combining flow velocimetry experiments and high-speed tracking of the pillars. The waves form an angle ±β with the primary flow direction that depends on the geometry of the pillar array. If the canopy is composed of flexible structures, the passage of a wave deflects the structures locally in a manner reminiscent of the emergence of the Monami waves observed in inertial turbulence over canopies of vegetation. Due to the analogies with classical (inertial) canopy turbulence, we name our observed phenomenon canopy elastic turbulence.

AB - In a viscoelastic flow over a microfluidic canopy of polymeric pillars, we report the spontaneous emergence of waves in the form of propagating regions of low flow velocity compared to the surrounding flow. The occurrence of the wave is chaotic and shows characteristics of elastic turbulence. We systematically study the coupling between the low-velocity wave and the microfluidic canopy by combining flow velocimetry experiments and high-speed tracking of the pillars. The waves form an angle ±β with the primary flow direction that depends on the geometry of the pillar array. If the canopy is composed of flexible structures, the passage of a wave deflects the structures locally in a manner reminiscent of the emergence of the Monami waves observed in inertial turbulence over canopies of vegetation. Due to the analogies with classical (inertial) canopy turbulence, we name our observed phenomenon canopy elastic turbulence.

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Canopy elastic turbulence: Spontaneous formation of waves in beds of slender microposts

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