Torsional fracture of viscoelastic liquid bridges

San To Chan; Frank P.A. van Berlo; Hammad A. Faizi; Atsushi Matsumoto; Simon J. Haward; Patrick D. Anderson; Amy Q. Shen

doi:10.1073/pnas.2104790118

Torsional fracture of viscoelastic liquid bridges

San To Chan, Frank P.A. van Berlo, Hammad A. Faizi, Atsushi Matsumoto, Simon J. Haward, Patrick D. Anderson, Amy Q. Shen (Corresponding author)

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

15 Citations (Scopus)

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Abstract

Short liquid bridges are stable under the action of surface tension. In applications like electronic packaging, food engineering, and additive manufacturing, this poses challenges to the clean and fast dispensing of viscoelastic fluids. Here, we investigate how viscoelastic liquid bridges can be destabilized by torsion. By combining high-speed imaging and numerical simulation, we show that concave surfaces of liquid bridges can localize shear, in turn localizing normal stresses and making the surface more concave. Such positive feedback creates an indent, which propagates toward the center and leads to breakup of the liquid bridge. The indent formation mechanism closely resembles edge fracture, an often undesired viscoelastic flow instability characterized by the sudden indentation of the fluid’s free surface when the fluid is subjected to shear. By applying torsion, even short, capillary stable liquid bridges can be broken in the order of 1 s. This may lead to the development of dispensing protocols that reduce substrate contamination by the satellite droplets and long capillary tails formed by capillary retraction, which is the current mainstream industrial method for destabilizing viscoelastic liquid bridges.

Original language	English
Article number	e2104790118
Number of pages	12
Journal	Proceedings of the National Academy of Sciences of the United States of America (PNAS)
Volume	118
Issue number	24
DOIs	https://doi.org/10.1073/pnas.2104790118
Publication status	Published - 15 Jun 2021

Funding

ACKNOWLEDGMENTS. S.T.C., A.M., S.J.H., and A.Q.S. acknowledge the support of Okinawa Institute of Science and Technology Graduate University with subsidy funding from the Cabinet Office, Government of Japan. S.T.C., A.M., S.J.H., and A.Q.S. also acknowledge financial support from the Japanese Society for the Promotion of Science (JSPS) (Grants 21J10517, 19K15641, 18K03958, 21K03884, and 18H01135) and the Joint Research Projects supported by the JSPS and the Swiss National Science Foundation. F.P.A.v.B. and P.D.A. thank Dr. M. A. Hulsen for providing access to the Toolkit for Finite Element Method software libraries. S.T.C. and H.A.F. thank Prof. H. C. Shum for fruitful discussions that helped conceive the research idea. We thank Prof. G. H. McKinley and Prof. R. I. Tanner for helpful comments.

Keywords

Contact printing
Edge fracture
Flow instability
Liquid bridge
Viscoelasticity

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10.1073/pnas.2104790118

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title = "Torsional fracture of viscoelastic liquid bridges",

abstract = "Short liquid bridges are stable under the action of surface tension. In applications like electronic packaging, food engineering, and additive manufacturing, this poses challenges to the clean and fast dispensing of viscoelastic fluids. Here, we investigate how viscoelastic liquid bridges can be destabilized by torsion. By combining high-speed imaging and numerical simulation, we show that concave surfaces of liquid bridges can localize shear, in turn localizing normal stresses and making the surface more concave. Such positive feedback creates an indent, which propagates toward the center and leads to breakup of the liquid bridge. The indent formation mechanism closely resembles edge fracture, an often undesired viscoelastic flow instability characterized by the sudden indentation of the fluid{\textquoteright}s free surface when the fluid is subjected to shear. By applying torsion, even short, capillary stable liquid bridges can be broken in the order of 1 s. This may lead to the development of dispensing protocols that reduce substrate contamination by the satellite droplets and long capillary tails formed by capillary retraction, which is the current mainstream industrial method for destabilizing viscoelastic liquid bridges.",

keywords = "Contact printing, Edge fracture, Flow instability, Liquid bridge, Viscoelasticity",

author = "Chan, {San To} and {van Berlo}, {Frank P.A.} and Faizi, {Hammad A.} and Atsushi Matsumoto and Haward, {Simon J.} and Anderson, {Patrick D.} and Shen, {Amy Q.}",

note = "Funding Information: ACKNOWLEDGMENTS. S.T.C., A.M., S.J.H., and A.Q.S. acknowledge the support of Okinawa Institute of Science and Technology Graduate University with subsidy funding from the Cabinet Office, Government of Japan. S.T.C., A.M., S.J.H., and A.Q.S. also acknowledge financial support from the Japanese Society for the Promotion of Science (JSPS) (Grants 21J10517, 19K15641, 18K03958, 21K03884, and 18H01135) and the Joint Research Projects supported by the JSPS and the Swiss National Science Foundation. F.P.A.v.B. and P.D.A. thank Dr. M. A. Hulsen for providing access to the Toolkit for Finite Element Method software libraries. S.T.C. and H.A.F. thank Prof. H. C. Shum for fruitful discussions that helped conceive the research idea. We thank Prof. G. H. McKinley and Prof. R. I. Tanner for helpful comments. Publisher Copyright: {\textcopyright} 2021 National Academy of Sciences. All rights reserved.",

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month = jun,

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doi = "10.1073/pnas.2104790118",

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AU - van Berlo, Frank P.A.

AU - Faizi, Hammad A.

AU - Matsumoto, Atsushi

AU - Haward, Simon J.

AU - Anderson, Patrick D.

AU - Shen, Amy Q.

N1 - Funding Information: ACKNOWLEDGMENTS. S.T.C., A.M., S.J.H., and A.Q.S. acknowledge the support of Okinawa Institute of Science and Technology Graduate University with subsidy funding from the Cabinet Office, Government of Japan. S.T.C., A.M., S.J.H., and A.Q.S. also acknowledge financial support from the Japanese Society for the Promotion of Science (JSPS) (Grants 21J10517, 19K15641, 18K03958, 21K03884, and 18H01135) and the Joint Research Projects supported by the JSPS and the Swiss National Science Foundation. F.P.A.v.B. and P.D.A. thank Dr. M. A. Hulsen for providing access to the Toolkit for Finite Element Method software libraries. S.T.C. and H.A.F. thank Prof. H. C. Shum for fruitful discussions that helped conceive the research idea. We thank Prof. G. H. McKinley and Prof. R. I. Tanner for helpful comments. Publisher Copyright: © 2021 National Academy of Sciences. All rights reserved.

PY - 2021/6/15

Y1 - 2021/6/15

N2 - Short liquid bridges are stable under the action of surface tension. In applications like electronic packaging, food engineering, and additive manufacturing, this poses challenges to the clean and fast dispensing of viscoelastic fluids. Here, we investigate how viscoelastic liquid bridges can be destabilized by torsion. By combining high-speed imaging and numerical simulation, we show that concave surfaces of liquid bridges can localize shear, in turn localizing normal stresses and making the surface more concave. Such positive feedback creates an indent, which propagates toward the center and leads to breakup of the liquid bridge. The indent formation mechanism closely resembles edge fracture, an often undesired viscoelastic flow instability characterized by the sudden indentation of the fluid’s free surface when the fluid is subjected to shear. By applying torsion, even short, capillary stable liquid bridges can be broken in the order of 1 s. This may lead to the development of dispensing protocols that reduce substrate contamination by the satellite droplets and long capillary tails formed by capillary retraction, which is the current mainstream industrial method for destabilizing viscoelastic liquid bridges.

AB - Short liquid bridges are stable under the action of surface tension. In applications like electronic packaging, food engineering, and additive manufacturing, this poses challenges to the clean and fast dispensing of viscoelastic fluids. Here, we investigate how viscoelastic liquid bridges can be destabilized by torsion. By combining high-speed imaging and numerical simulation, we show that concave surfaces of liquid bridges can localize shear, in turn localizing normal stresses and making the surface more concave. Such positive feedback creates an indent, which propagates toward the center and leads to breakup of the liquid bridge. The indent formation mechanism closely resembles edge fracture, an often undesired viscoelastic flow instability characterized by the sudden indentation of the fluid’s free surface when the fluid is subjected to shear. By applying torsion, even short, capillary stable liquid bridges can be broken in the order of 1 s. This may lead to the development of dispensing protocols that reduce substrate contamination by the satellite droplets and long capillary tails formed by capillary retraction, which is the current mainstream industrial method for destabilizing viscoelastic liquid bridges.

KW - Contact printing

KW - Edge fracture

KW - Flow instability

KW - Liquid bridge

KW - Viscoelasticity

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DO - 10.1073/pnas.2104790118

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ER -

Torsional fracture of viscoelastic liquid bridges

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