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Received March 11, 2022
Accepted April 24, 2022
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Facile microfluidic method for measuring the relaxation time of dilute polymer solution based on viscoelastic particle focusing
1Department of Energy Systems Research, Ajou University, Suwon 16499, Korea 2Department of Chemical Engineering, Ajou University, Suwon 16499, Korea
tsshim@ajou.ac.kr
Korean Journal of Chemical Engineering, September 2022, 39(9), 2318-2323(6), 10.1007/s11814-022-1152-x
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Abstract
The relaxation time of a viscoelastic fluid is an essential parameter for characterizing the degree of elasticity. However, measuring the relaxation time of dilute polymer solutions with low viscosity using conventional rotational rheometers remains challenging because of the low instrument sensitivity. In this study, we demonstrate an efficient microfluidic method for measuring the relaxation time of a dilute polymer solution by utilizing elasticitydriven lateral particle migration in a microchannel. First, the previous theoretical model was refined, based on the Oldroyd-B constitutive equation, in order to predict lateral particle migration in a viscoelastic fluid with constant shear viscosity, considering the inlet and finite particle size effects. This model was utilized to determine the relaxation times of dilute poly(ethylene oxide) (PEO) aqueous solutions. Direct comparison of the measured relaxation times with those obtained from Zimm theory verified the reliability of the proposed method. The current approach is expected to be useful in characterizing the relaxation times of a wide range of polymer solutions.
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References
Bird RB, Armstrong RC, Hassager O, Dynamics of polymeric liquids, Wiley Interscience, New York (1987).
Larson RG, The structure and rheology of complex fluids, Oxford University Press, New York (1999).
Kang K, Lee SS, Hyun K, Lee SJ, Kim JM, Nat. Commun., 4, 2567 (2013)
Zilz J, Schafer C, Wagner C, Poole RJ, Alves MA, Lindner A, Lab Chip, 14, 351 (2014)
Macosko CW, Rheology: principles, measurements, and applications, Wiley-VCH (1994).
Rodd LE, Scott TP, Cooper-White JJ, McKinley GH, Appl. Rheol., 15, 12 (2004)
Del Giudice F, D'Avino G, Greco F, De Santo I, Netti PA, Maffettone PL, Lab Chip, 15, 783 (2015)
Giudice FD, Haward SJ, Shen AQ, J. Rheol., 61, 327 (2017)
Clasen C, Plog JP, Kulicke WM, Owens M, Macosko C, Scriven LE, Verani M, McKinley GH, J. Rheol., 50, 849 (2006)
Kim JM, Korean J. Chem. Eng., 32, 2406 (2015)
Kim DY, Kim JM, Korean J. Chem. Eng., 36, 837 (2019)
Shiriny A, Bayareh M, Nadooshan AA, Korean J. Chem. Eng., 38, 1686 (2021)
Kim B, Lee SS, Yoo TH, Kim S, Kim SY, Choi SH, Kim JM, Sci. Adv., 5, eaav4819 (2019)
Guazzelli E, Morris JF, A physical introduction to suspension dynamics, Cambridge University Press, Cambridge (2012).
Ho BP, Leal LG, J. Fluid Mech., 76, 783 (1976)
Karnis A, Mason SG, Goldsmith HL, Nature, 200, 159 (1963)
Leshansky AM, Bransky A, Korin N, Dinnar U, Phys. Rev. Lett., 98, 234501 (2007)
D'Avino G, Romeo G, Villone MM, Greco F, Netti PA, Maffettone PL, Lab Chip, 12, 1638 (2012)
Romeo G, D'Avino G, Greco F, Netti PA, Maffettone PL, Lab Chip, 13, 2802 (2013)
D'Avino G, Greco F, Maffettone PL, Annu. Rev. Fluid Mech., 49, 341 (2017)
James DF, Annu. Rev. Fluid Mech., 41, 129 (2009)
Graessley WW, Polymer, 21, 258 (1980)
Tirtaatmadja V, McKinley GH, Cooper-White JJ, Phys. Fluids, 18, 043101 (2006)
Rubinstein M, Colby RH, Polymer physics, Oxford University Press, Oxford (2003).
Yang S, Kim JY, Lee SJ, Lee SS, Kim JM, Lab Chip, 11, 266 (2011)
Rodd LE, Scott TP, Boger DV, Cooper-White JJ, McKinley GH, J. Non-Newton. Fluid Mech., 129, 1 (2005)
Rodd LE, Cooper-White JJ, Boger DV, McKinley GH, J. Non-Newton. Fluid Mech., 143, 170 (2007)
Casanellas L, Alves MA, Poole RJ, Lerouge S, Lindner A, Soft Matter, 12, 6167 (2016)
Liu YG, Jun YG, Steinberg V, J. Rheol., 53, 1069 (2009)
Larson RG, The structure and rheology of complex fluids, Oxford University Press, New York (1999).
Kang K, Lee SS, Hyun K, Lee SJ, Kim JM, Nat. Commun., 4, 2567 (2013)
Zilz J, Schafer C, Wagner C, Poole RJ, Alves MA, Lindner A, Lab Chip, 14, 351 (2014)
Macosko CW, Rheology: principles, measurements, and applications, Wiley-VCH (1994).
Rodd LE, Scott TP, Cooper-White JJ, McKinley GH, Appl. Rheol., 15, 12 (2004)
Del Giudice F, D'Avino G, Greco F, De Santo I, Netti PA, Maffettone PL, Lab Chip, 15, 783 (2015)
Giudice FD, Haward SJ, Shen AQ, J. Rheol., 61, 327 (2017)
Clasen C, Plog JP, Kulicke WM, Owens M, Macosko C, Scriven LE, Verani M, McKinley GH, J. Rheol., 50, 849 (2006)
Kim JM, Korean J. Chem. Eng., 32, 2406 (2015)
Kim DY, Kim JM, Korean J. Chem. Eng., 36, 837 (2019)
Shiriny A, Bayareh M, Nadooshan AA, Korean J. Chem. Eng., 38, 1686 (2021)
Kim B, Lee SS, Yoo TH, Kim S, Kim SY, Choi SH, Kim JM, Sci. Adv., 5, eaav4819 (2019)
Guazzelli E, Morris JF, A physical introduction to suspension dynamics, Cambridge University Press, Cambridge (2012).
Ho BP, Leal LG, J. Fluid Mech., 76, 783 (1976)
Karnis A, Mason SG, Goldsmith HL, Nature, 200, 159 (1963)
Leshansky AM, Bransky A, Korin N, Dinnar U, Phys. Rev. Lett., 98, 234501 (2007)
D'Avino G, Romeo G, Villone MM, Greco F, Netti PA, Maffettone PL, Lab Chip, 12, 1638 (2012)
Romeo G, D'Avino G, Greco F, Netti PA, Maffettone PL, Lab Chip, 13, 2802 (2013)
D'Avino G, Greco F, Maffettone PL, Annu. Rev. Fluid Mech., 49, 341 (2017)
James DF, Annu. Rev. Fluid Mech., 41, 129 (2009)
Graessley WW, Polymer, 21, 258 (1980)
Tirtaatmadja V, McKinley GH, Cooper-White JJ, Phys. Fluids, 18, 043101 (2006)
Rubinstein M, Colby RH, Polymer physics, Oxford University Press, Oxford (2003).
Yang S, Kim JY, Lee SJ, Lee SS, Kim JM, Lab Chip, 11, 266 (2011)
Rodd LE, Scott TP, Boger DV, Cooper-White JJ, McKinley GH, J. Non-Newton. Fluid Mech., 129, 1 (2005)
Rodd LE, Cooper-White JJ, Boger DV, McKinley GH, J. Non-Newton. Fluid Mech., 143, 170 (2007)
Casanellas L, Alves MA, Poole RJ, Lerouge S, Lindner A, Soft Matter, 12, 6167 (2016)
Liu YG, Jun YG, Steinberg V, J. Rheol., 53, 1069 (2009)
