Electrophoresis



For specific types of electrophoresis (for example, the process of administering medicine, iontophoresis), see electrophoresis (disambiguation).

Electrophoresis is the most known electrokinetic phenomena.

Generally, electrophoresis is the motion of dielectrophoresis.

 

Electrophoresis occurs because particles dispersed in a fluid almost always carry an electric surface charge. An electric field exerts electrostatic Coulomb force on the particles through these charges.

Another force is electrostatic as well. It is known from double layer theory that all surface charges in fluids are screened with a stress. This part of the force that is applied to the particle body is called electrophoretic retardation force.

There is one more electric force, which is associated with deviation of the double layer from spherical symmetry and diffuse layer. This force is called the electrophoretic relaxation force

All these forces are balanced with hydrodynamic friction, which affects all bodies moving in viscous fluids with low electrophoretic mobility μe as coefficient of proprtionality between particle speed and electric field strength:

\mu_e = {v \over E}

Multiple theories were developed during 20th century for calculating this parameter. Ref. 1 provides an overview. Here are some of the most general conclusions.

Theory

 

The most known and widely used theory of electrophoresis was developed by Smoluchowski in 1903 [9], according to whom the electrophoretic mobility is

\mu_e = \frac{\varepsilon\varepsilon_0\zeta}{\eta},

where ε is the slipping plane in the double layer).

Smoluchowski theory is very powerful because it is valid for Debye length κ-1. However, the Debye length must be important for electrophoresis, as follows from the Figure on the right. Increasing the thickness of the DL leads to moving the point of retardation force further from the particle surface. The thicker the DL, the smaller retardation force must be.

Detailed theoretical analysis proved that Smoluchowski theory is valid only for a sufficiently thin DL, when the Debye length is much smaller than the particle radius a:

κa > > 1

This model of the "thin Double Layer" offers tremendous simplifications not only for electrophoresis theory but for many other electrokinetic theories. This model is valid for most aqueous systems because the Debye length is only a few nanometers there. It breaks only for nano-ionic strength close to water.

Smoluchowski theory also neglects the contribution of Dukhin number

Du < < 1

The creation of an electrophoretic theory with a wider range of validity was a purpose of many studies during 20th century.

One of the most known considers an opposite asymptotic case when Debye length is larger than particle radius:

κa < 1

It is a "thick Double Layer" model. A corresponding electrophoretic theory was created by Huckel in 1924 [10]. It yields the following equation for electrophoretic mobility:

\mu_e = \frac{2\varepsilon\varepsilon_0\zeta}{3\eta},

This model can be useful for some nano-colloids and non-polar fluids, where the Debye length is much larger.

There are several analytical theories that incorporate Dukhin number. Early pioneering work in that direction dates back to Overbeek [11] and Booth [12].

Modern, rigorous theories that are valid for any Zeta potential and often any κa, stem mostly from the Ukrainian (Dukhin, Shilov and others) and Australian (O'Brien, White, Hunter and others) Schools.

Historically the first one was Dukhin-Semenikhin theory [13]. Similar theory was created 10 years later by O'Brien and Hunter [14]. Assuming thin Double Layer, these theories would yield results that are very close to the numerical solution provided by O'Brien and White [15].

Applications

There are many applications of electrophoresis for measurements and various operations with particulates

Measurement

electrophoresis is used for studying properties of electrophoretic light scattering. These methods are described in details in the "Fundamentals of Interface and Colloid Science", by Lyklema [16]

Gel electrophoresis

gel and separated on the basis of their electrophoretic mobility.[17] (The gel greatly retards the mobility of all molecules present.)[18]

Electrophoretic displays

Electrophoretic displays (EPD's) are a class of information display that form images by electrophoretic motion of charged, colored pigment particles. Products incorporating electrophoretic displays include the Sony Librie electronic book reader, and the iRex iLiad e-newspaper tablet, both of which use electrophoretic films manufactured by E Ink Corporation.

Electrophoretic fingerprinting

Electrophoresis is also used in the process of DNA fingerprinting. Certain DNA segments that vary vastly among humans are cut at recognition sites by restriction enzymes (restriction endonuclease). After the resulting DNA fragments are run through electrophoresis, the distance between bands are measured and recorded as the DNA "fingerprint."

Electrophoretic deposition

Coatings, such as paint or ceramics, can be applied by electrophoretic deposition. The technique can even be used for 3-D printing.

References

  1. ^ Reuss, F.F. Mem.Soc.Imperiale Naturalistes de Moscow, 2, 327 1809
  2. ^ Lyklema, J. “Fundamentals of Interface and Colloid Science”, vol.2, page.3.208, 1995
  3. ^ Hunter, R.J. "Foundations of Colloid Science", Oxford University Press, 1989
  4. ^ Dukhin, S.S. & Derjaguin, B.V. "Electrokinetic Phenomena", J.Willey and Sons, 1974
  5. ^ Russel, W.B., Saville, D.A. and Schowalter, W.R. “Colloidal Dispersions”, Cambridge University Press,1989
  6. ^ Kruyt, H.R. “Colloid Science”, Elsevier: Volume 1, Irreversible systems, (1952)
  7. ^ Dukhin, A.S. and Goetz, P.J. "Ultrasound for characterizing colloids", Elsevier, 2002
  8. ^ ”Measurement and Interpretation of Electrokinetic Phenomena”, International Union of Pure and Applied Chemistry, Technical Report, published in Pure Appl.Chem., vol 77, 10, pp.1753-1805, 2005
  9. ^ M. von Smoluchowski, Bull. Int. Acad. Sci. Cracovie, 184 (1903)
  10. ^ Huckel, E., Physik.Z., 25, 204 (1924)
  11. ^ Overbeek, J.Th.G., Koll.Bith, 287 (1943)
  12. ^ Booth, F. Nature, 161, 83 (1948)
  13. ^ Dukhin, S.S. and Semenikhin, N.M. Koll.Zhur., 32, 366 (1970)
  14. ^ O'Brien, R.W. and Hunter, R.J. Can.J.Chem., 59, 1878 (1981)
  15. ^ O'Brien, R.W. and White, L.R. J.Chem.Soc.Faraday Trans. 2, 74, 1607, (1978)
  16. ^ Lyklema, J. "Fundamentals of Interface and Colloid Science", Academic Press, vol 2, (1995)
  17. ^ Comparison of electrophoretic migration of linear and supercoiled molecules. Focus 19:3 p.63 (1998).
  18. ^ Top ten fun facts for DNA electrophoresis. Focus 19:3 p.65 (1998).
  • http://gslc.genetics.utah.edu/units/activities/electrophoresis/
  • Voet and Voet, Biochemistry, John Whiley & sons. 1990.
  • Jahn, G. C., Hall, D.W., and Zam, S. G. 1986. A comparison of the life cycles of two Amblyospora (Microspora: Amblyosporidae) in the mosquitoes Culex salinarius and Culex tarsalis Coquillett. J. Florida Anti-Mosquito Assoc. 57, 24–27.
  • Khattak MN, Matthews RC. Genetic relatedness of Bordetella species as determined by macrorestriction digests resolved by pulsed-field gel electrophoresis. Int J Syst Bacteriol. 1993 Oct;43(4):659-64.
  • Barz, D.P.J., Ehrhard. P., Model and verification of electrokinetic flow and transport in a micro-electrophoresis device, Lab Chip, 2005, 5, 949 - 958.

ISO electrophoresis

See also
 
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Electrophoresis". A list of authors is available in Wikipedia.