Electrophoretic Motion of a Liquid Droplet within an Uncharged Cylindrical Pore
Electrophoretic motion of a liquid droplet within an
uncharged cylindrical pore is investigated theoretically in this study. It
is found that the boundary effect in terms of the reduction of droplet
mobility (droplet velocity per unit strength of the applied electric field)
is very significant when the double layer surrounding the droplet is
thick, and diminishes as it gets very thin. Moreover, the viscosity ratio
of the ambient fluid to the internal one, σ, is a crucial factor in
determining its electrophoretic behavior. The boundary effect is less
significant as the viscosity ratio gets high. Up to 70% mobility
reduction is observed when this ratio is low (σ = 0.01), whereas only
40% reduction when it is high (σ = 100). The results of this study can
be utilized in various fields of biotechnology, such as a biosensor or a
lab-on-a-chip device.
[1] Stone, H. A., and Kim, S., "Microfluidics: basic issues, applications, and
challenges," Aiche J., vol. 47, 2001, pp. 1250-1254.
[2] Rouhi, A. M., "Microreactors eyed for industrial use," Chem. Eng. News,
vol. 82, 2004, pp. 18-19.
[3] Vilkner, T., Janasek, D., and Manz, A., "Micro total analysis systems.
Recent developments," Anal. Chem., vol. 76, 2004, pp. 3373-3386.
[4] van. den Berg A. and Lammerink TSJ., Micro total analysis systems:
microfluidic aspects, integration concept and applications. Berlin:
Springer-Verlag, 1998, pp. 21-49.
[5] Manz A., Graber N., and Widmer H. M., "Miniaturized total chemical
analysis systems: a novel concept for chemical sensing, "Sens Actuators B
Chem., vol. 1, 1990, pp. 244.
[6] Utada AS, Lorenceau E, Link DR, Kaplan PD, Stone H. A., and Weitz D.
A., "Monodisperse double emulsions generated from a microcapillary
device," Science, vol. 308, 2005, pp. 537.
[7] Joanicot M., and Ajdari A, "Applied physics: droplet control for
microfluidics," Science, vol. 309, 2005, pp. 887.
[8] Dendukuri D., Tsoi K., Hatton T.A., and Doyle P.S., "Controlled
Synthesis of Non-Spherical Microparticles Using Microfluidics,"
Langmuir, vol. 21, 2005, pp. 2113-2116.
[9] Gunther A., Khan S. A., Thalmann M., Trachsel F., and Jensen K. F.,
"Transport and reaction in microscale segmented gas-Vliquid flow," Lab
Chip, vol.4, 2004, pp. 278.
[10] Linder V., Sia S. K., and Whitesides G. M., "Reagent-loaded cartridges
for valveless and automated fluid delivery in microfluidic devices," Anal
Chem., vol.77, 2005, pp. 64.
[11] Shestopalov I., Tice J. D., and Ismagilov R. F., "Multi-step synthesis of
nanoparticles performed on millisecond time scale in a microfluidic
droplet-based system," Lab Chip, vol.4, 2004, pp. 316.
[12] Parikesit, and G. Gildeprint Drukkerijen B.V., "Nanofluidic
electrokinetics," 2008.
[13] Booth F., "The cataphoresis of spherical fluid droplets in electrolytes," J.
Chem. Phys., vol.19, 1951, pp. 1331-1342.
[14] Levine S., and O-Brien R. N., "A theory of electrophoresis of charged
mercury drops in aqueous electrolyte solution," J. Colloid Interface Sci.,
vol.43, 1973, pp. 616-629.
[15] Baygents J. C., and Saville D. A., "Electrophoresis of drops and bubbles,"
J. Chem. Soc., Faraday Trans. vol.87, 1991, pp. 1883-1898.
[16] Baygents J. C., and Saville D. A., "Electrophoresis of small particles and
fluid globules in weak electrolytes," J. Colloid Interface Sci., vol.146,
1991, pp. 9-37.
[17] Ohshima H. J., "Electrokinetic phenomena in a concentrated dispersion
of charged mercury drops," Colloid Interface Sci., vol.218, 1999, pp.
535-544.
[18] Eric Lee, Jui-Der Kao, and Jyh-Ping Hsu, "Electrophoresis of a nonrigid
entity in a spherical cavity," J. Phys. Chem. B, vol.106, 2002, pp.
8790-8795.
[19] Lee E., Fu C.H., and Hsu J.P., "Dynamic Electrophoretic Mobility of a
Concentrated Dispersion of Particles with a Charge-Regulated Surface at
Arbitrary Potential," J. Colloid Interface Sci., vol.250, 2002, pp.
327-336.
[20] Keh H. J., and Anderson J. L., "Electrophoresis of a colloidal sphere in a
circular cylindrical pore," J. Fluid Mech., vol.153, 1985, pp. 417−439.
[21] Ennis J., and Anderson J. L., "Boundary effects on electrophoretic motion
of spherical particles for thick double layers and low zeta potential," J.
Colloid Interface Sci., vol.185, 1997, pp. 497−514.
[22] Shugai A., and Carnie S., "Electrophoretic motion of a spherical particle
with a thick double layer in bounded flows," J. Colloid Interface Sci.,
vol.213, 1999, pp. 298−315.
[23] Teubner M., "The motion of charged colloidal particles in electric fields,"
J. Chem. Phys., vol.76, 1982, pp. 5564−5573.
[24] Hsu J., and Chen Z., "Electrophoresis of a sphere along the axis of a
cylindrical pore: effects of double-Layer polarization and electroosmotic
flow," Langmuir, vol.23, 2007, pp. 6198−6204.
[25] Happel J., and Brenner H., Low Reynolds number hydrodynamics. M.
Nijhoff Boston, 1983.
[26] Hussaini M., and Zang T., "pectral methods in fluid dynamics," Annu.
Rev. Fluid Mech., vol.19, 1987, pp. 339-367.
[27] Von Smoluchowski, "Versuch einer mathematischen theorie der
koagulationskinetik kolloider losungen," Z. Phys. Chem., vol.92, 1917,
pp. 129-168.
[28] O'Brien, R. W., and White, L. R., "Electrophoretic mobility of a spherical
colloidal particle," J. Chem. Soc., Faraday Trans., vol.74, 1978, pp.
1607-1626.
[1] Stone, H. A., and Kim, S., "Microfluidics: basic issues, applications, and
challenges," Aiche J., vol. 47, 2001, pp. 1250-1254.
[2] Rouhi, A. M., "Microreactors eyed for industrial use," Chem. Eng. News,
vol. 82, 2004, pp. 18-19.
[3] Vilkner, T., Janasek, D., and Manz, A., "Micro total analysis systems.
Recent developments," Anal. Chem., vol. 76, 2004, pp. 3373-3386.
[4] van. den Berg A. and Lammerink TSJ., Micro total analysis systems:
microfluidic aspects, integration concept and applications. Berlin:
Springer-Verlag, 1998, pp. 21-49.
[5] Manz A., Graber N., and Widmer H. M., "Miniaturized total chemical
analysis systems: a novel concept for chemical sensing, "Sens Actuators B
Chem., vol. 1, 1990, pp. 244.
[6] Utada AS, Lorenceau E, Link DR, Kaplan PD, Stone H. A., and Weitz D.
A., "Monodisperse double emulsions generated from a microcapillary
device," Science, vol. 308, 2005, pp. 537.
[7] Joanicot M., and Ajdari A, "Applied physics: droplet control for
microfluidics," Science, vol. 309, 2005, pp. 887.
[8] Dendukuri D., Tsoi K., Hatton T.A., and Doyle P.S., "Controlled
Synthesis of Non-Spherical Microparticles Using Microfluidics,"
Langmuir, vol. 21, 2005, pp. 2113-2116.
[9] Gunther A., Khan S. A., Thalmann M., Trachsel F., and Jensen K. F.,
"Transport and reaction in microscale segmented gas-Vliquid flow," Lab
Chip, vol.4, 2004, pp. 278.
[10] Linder V., Sia S. K., and Whitesides G. M., "Reagent-loaded cartridges
for valveless and automated fluid delivery in microfluidic devices," Anal
Chem., vol.77, 2005, pp. 64.
[11] Shestopalov I., Tice J. D., and Ismagilov R. F., "Multi-step synthesis of
nanoparticles performed on millisecond time scale in a microfluidic
droplet-based system," Lab Chip, vol.4, 2004, pp. 316.
[12] Parikesit, and G. Gildeprint Drukkerijen B.V., "Nanofluidic
electrokinetics," 2008.
[13] Booth F., "The cataphoresis of spherical fluid droplets in electrolytes," J.
Chem. Phys., vol.19, 1951, pp. 1331-1342.
[14] Levine S., and O-Brien R. N., "A theory of electrophoresis of charged
mercury drops in aqueous electrolyte solution," J. Colloid Interface Sci.,
vol.43, 1973, pp. 616-629.
[15] Baygents J. C., and Saville D. A., "Electrophoresis of drops and bubbles,"
J. Chem. Soc., Faraday Trans. vol.87, 1991, pp. 1883-1898.
[16] Baygents J. C., and Saville D. A., "Electrophoresis of small particles and
fluid globules in weak electrolytes," J. Colloid Interface Sci., vol.146,
1991, pp. 9-37.
[17] Ohshima H. J., "Electrokinetic phenomena in a concentrated dispersion
of charged mercury drops," Colloid Interface Sci., vol.218, 1999, pp.
535-544.
[18] Eric Lee, Jui-Der Kao, and Jyh-Ping Hsu, "Electrophoresis of a nonrigid
entity in a spherical cavity," J. Phys. Chem. B, vol.106, 2002, pp.
8790-8795.
[19] Lee E., Fu C.H., and Hsu J.P., "Dynamic Electrophoretic Mobility of a
Concentrated Dispersion of Particles with a Charge-Regulated Surface at
Arbitrary Potential," J. Colloid Interface Sci., vol.250, 2002, pp.
327-336.
[20] Keh H. J., and Anderson J. L., "Electrophoresis of a colloidal sphere in a
circular cylindrical pore," J. Fluid Mech., vol.153, 1985, pp. 417−439.
[21] Ennis J., and Anderson J. L., "Boundary effects on electrophoretic motion
of spherical particles for thick double layers and low zeta potential," J.
Colloid Interface Sci., vol.185, 1997, pp. 497−514.
[22] Shugai A., and Carnie S., "Electrophoretic motion of a spherical particle
with a thick double layer in bounded flows," J. Colloid Interface Sci.,
vol.213, 1999, pp. 298−315.
[23] Teubner M., "The motion of charged colloidal particles in electric fields,"
J. Chem. Phys., vol.76, 1982, pp. 5564−5573.
[24] Hsu J., and Chen Z., "Electrophoresis of a sphere along the axis of a
cylindrical pore: effects of double-Layer polarization and electroosmotic
flow," Langmuir, vol.23, 2007, pp. 6198−6204.
[25] Happel J., and Brenner H., Low Reynolds number hydrodynamics. M.
Nijhoff Boston, 1983.
[26] Hussaini M., and Zang T., "pectral methods in fluid dynamics," Annu.
Rev. Fluid Mech., vol.19, 1987, pp. 339-367.
[27] Von Smoluchowski, "Versuch einer mathematischen theorie der
koagulationskinetik kolloider losungen," Z. Phys. Chem., vol.92, 1917,
pp. 129-168.
[28] O'Brien, R. W., and White, L. R., "Electrophoretic mobility of a spherical
colloidal particle," J. Chem. Soc., Faraday Trans., vol.74, 1978, pp.
1607-1626.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:55088", author = "Cheng-Hsuan Huang and Eric Lee", title = "Electrophoretic Motion of a Liquid Droplet within an Uncharged Cylindrical Pore", abstract = "Electrophoretic motion of a liquid droplet within an
uncharged cylindrical pore is investigated theoretically in this study. It
is found that the boundary effect in terms of the reduction of droplet
mobility (droplet velocity per unit strength of the applied electric field)
is very significant when the double layer surrounding the droplet is
thick, and diminishes as it gets very thin. Moreover, the viscosity ratio
of the ambient fluid to the internal one, σ, is a crucial factor in
determining its electrophoretic behavior. The boundary effect is less
significant as the viscosity ratio gets high. Up to 70% mobility
reduction is observed when this ratio is low (σ = 0.01), whereas only
40% reduction when it is high (σ = 100). The results of this study can
be utilized in various fields of biotechnology, such as a biosensor or a
lab-on-a-chip device.", keywords = "Cylindrical pore, Electrophoresis, Lab-on-a-chip,
Liquid droplet", volume = "5", number = "5", pages = "418-6", }
