Extensional rheometry of mobile fluids. Part I: OUBER, an optimized uniaxial and biaxial extensional rheometer
Extensional rheometry of mobile fluids. Part I: OUBER, an optimized uniaxial and biaxial extensional rheometer
Numerical optimization of a “six-arm cross-slot” device yields several three-dimensional shapes of fluidic channels that impose close approximations to an ideal uniaxial (biaxial) stagnation point extensional flow under the constraints of having four inlets and two outlets (two inlets and four outlets) and for Newtonian creeping flow. One of the numerically designed geometries is considered suitable for fabrication at the microscale, and numerical simulations with the Oldroyd-B and Phan-Thien and Tanner models confirm that the optimal flow fields are observed in the geometry for both constant viscosity and shear thinning viscoelastic fluids. The geometry, named the optimized uniaxial and biaxial extensional rheometer (OUBER), is microfabricated with high precision by selective laser-induced etching of a fused-silica substrate. Employing a refractive index-matched viscous Newtonian fluid, microtomographic-particle image velocimetry enables the measurement of the flow field in a substantial volume around the stagnation point. The flow velocimetry, performed at low Reynolds number (
), confirms the accurate imposition of the desired and predicted flows, with a pure extensional flow at an essentially uniform deformation rate being applied over a wide region around the stagnation point. In Part II of this paper [Haward et al., J. Rheol. 67, 1011–1030 (2023)], pressure drop measurements in the OUBER geometry are used to assess the uniaxial and biaxial extensional rheometry of dilute polymeric solutions, in comparison to measurements made in planar extension using an optimized-shape cross-slot extensional rheometer
995–1009
Haward, Simon J.
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Pimenta, Francisco
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Varchanis, Stylianos
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Carlson, Daniel W.
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Toda-Peters, Kazumi
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Alves, Manuel A.
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Shen, Amy Q.
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Haward, Simon J.
5693ac8d-5d84-4519-869f-9ba04077e160
Pimenta, Francisco
7deb2e0a-6fc1-4672-a820-2817fecdba98
Varchanis, Stylianos
e6452dfc-1824-4a28-bb93-5353b9fd57c6
Carlson, Daniel W.
c0f88797-732c-46ef-8e74-a5186d4733bf
Toda-Peters, Kazumi
01123e8b-178a-47d8-9f9d-1d58cde047fd
Alves, Manuel A.
3d603c89-4ab5-4294-a867-c0fe87d4566b
Shen, Amy Q.
f04513a5-fedd-4759-958a-674855da2600
Haward, Simon J., Pimenta, Francisco, Varchanis, Stylianos, Carlson, Daniel W., Toda-Peters, Kazumi, Alves, Manuel A. and Shen, Amy Q.
(2023)
Extensional rheometry of mobile fluids. Part I: OUBER, an optimized uniaxial and biaxial extensional rheometer.
Journal of Rheology, 67 (5), .
(doi:10.1122/8.0000659).
Abstract
Numerical optimization of a “six-arm cross-slot” device yields several three-dimensional shapes of fluidic channels that impose close approximations to an ideal uniaxial (biaxial) stagnation point extensional flow under the constraints of having four inlets and two outlets (two inlets and four outlets) and for Newtonian creeping flow. One of the numerically designed geometries is considered suitable for fabrication at the microscale, and numerical simulations with the Oldroyd-B and Phan-Thien and Tanner models confirm that the optimal flow fields are observed in the geometry for both constant viscosity and shear thinning viscoelastic fluids. The geometry, named the optimized uniaxial and biaxial extensional rheometer (OUBER), is microfabricated with high precision by selective laser-induced etching of a fused-silica substrate. Employing a refractive index-matched viscous Newtonian fluid, microtomographic-particle image velocimetry enables the measurement of the flow field in a substantial volume around the stagnation point. The flow velocimetry, performed at low Reynolds number (
), confirms the accurate imposition of the desired and predicted flows, with a pure extensional flow at an essentially uniform deformation rate being applied over a wide region around the stagnation point. In Part II of this paper [Haward et al., J. Rheol. 67, 1011–1030 (2023)], pressure drop measurements in the OUBER geometry are used to assess the uniaxial and biaxial extensional rheometry of dilute polymeric solutions, in comparison to measurements made in planar extension using an optimized-shape cross-slot extensional rheometer
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e-pub ahead of print date: 25 July 2023
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Local EPrints ID: 507352
URI: http://eprints.soton.ac.uk/id/eprint/507352
PURE UUID: 65cd65a9-043d-43c0-90c5-6f86dd305bcb
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Date deposited: 04 Dec 2025 18:01
Last modified: 05 Dec 2025 03:03
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Author:
Simon J. Haward
Author:
Francisco Pimenta
Author:
Stylianos Varchanis
Author:
Daniel W. Carlson
Author:
Kazumi Toda-Peters
Author:
Manuel A. Alves
Author:
Amy Q. Shen
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