- Electrohydrodynamics
Electrohydrodynamics (EHD), also known as electro-fluid-dynamics (EFD) or electrokinetics, is the study of the dynamics of electrically conducting fluid. It is the study of the motions of
ion ised particles or molecules and their interactions withelectric field s and the surrounding fluid. The term may be considered to be synonymous with the rather elaborate electrostrictive hydrodynamics. EHD covers the following types of particle and fluid transport mechanisms:Electrophoresis , electrokinesis,dielectrophoresis ,electro-osmosis , andelectrorotation . In general, the phenomena relate to the direct conversion ofelectrical energy intokinetic energy , and "vice versa".In the first instance, shaped
electrostatic field s createhydrostatic pressure (or motion) indielectric media . When such media arefluid s, aflow is produced. If the dielectric is avacuum or asolid , no flow is produced. Such flow can be directed against theelectrode s, generally to move the electrodes. In such case, the moving structure acts as anelectric motor . Practical fields of interest of EHD are the commonair ioniser ,Electrohydrodynamic thruster s and EHD cooling systems.In the second instance, the converse takes place. A powered flow of medium within a shaped electrostatic field adds energy to the system which is picked up as a
potential difference by electrodes. In such case, the structure acts as anelectrical generator .Electrokinesis
Electrokinesis is the particle or
fluid transport produced by an electric field acting on a fluid having a net mobile charge. (See-kinesis for explanation and further uses of the kinesis suffix.) Electrokinesis was first observed by Reuss in 1809 and has been studied extensively since the 19th century. Such study is known as electrohydrodynamics or electrokinetics, and was documented byThomas Townsend Brown in 1921. It was later refined in scientific terms during the 1930s in conjunction with Dr. Paul Alfred Biefeld. The flow rate in such a mechanism is linear in theelectric field . Electrokinesis is of considerable practical importance inmicrofluidics , since it offers a way to manipulate and convey fluids in microsystems using only electric fields, with no moving parts.The force acting on the fluid, is given by the equation:
:
If the electrodes are free to move within the fluid, while keeping their distance fixed from each other, then such a force will actually propel the electrodes with respect to the fluid.
Electrokinesis has also been observed in biology, where it was found to cause physical damage to neurons by inciting movement in their membranes.cite book
last = Patterson
first = Michael
authorlink =
coauthors = Kesner, Raymond
title = Electrical Stimulation Research Techniques
publisher = Academic Press
year = 1981
location =
pages =
url =
doi =
id = ISBN 0-12-547440-7] [cite book
last = Elul
first = R.J.
authorlink =
coauthors =
title = Fixed charge in the cell membrane
publisher =
year = 1967
location =
pages =
url =
doi =
id = ] It is also discussed in R.J.Elul's "Fixed charge in the cell membrane" (1967).Water electrokinetics
In
October 2003 , Dr. Daniel Kwok, Dr. Larry Kostiuk and two graduate students from theUniversity of Alberta revealed a new method of hydrodynamic to electricalenergy conversion by exploiting the natural electrokinetic properties of a liquid such as ordinarytap water , by pumping fluids through tiny microchannels with a pressure difference. This technology could some day provide a practical and clean energy storage device, replacing today's batteries, for devices such as mobile phones or calculators which would be charged up by simply pumping water to highpressure . Pressure would then be released on demand, for fluid flow to take place over the microchannels. When water travels over a surface, the ions that it is made up of "rub" against the solid, leaving the surface slightly charged. Kinetic energy from the moving ions would be thus converted to electrical energy. Although the power generated from a single channel is extremely small, millions of parallel channels can be used to increase the power output.Actually, this phenomenon, calledstreaming potential , has been well-known for about 200 years.Fact|date=August 2007Electrokinetic Instabilities
The fluid flow in
microfluidic and nanofluidic devices are often stable and strongly damped by viscous forces (withReynold's number s of order unity or smaller). However, heterogeneous ionic conductivity fields in the presence of appliedelectric field s can, under certain conditions, generate an unstable flow field owing to electrokinetic instabilities (EKI). Conductivity gradients are prevalent in on-chip electrokinetic processes such as preconcentration methods (e.g. field amplified sample stacking andisoelectric focusing ), multidimensional assays, and systems with poorly specified sample chemistry. The dynamics and periodic morphology of electrokinetic instabilities are similar to other systems with Rayleigh–Taylor instabilities.Electrokinetic instabilities can be leveraged for rapid
mixing or can cause undesirable dispersion in sample injection, separation and stacking. These instabilities are caused by a coupling of electric fields and ionic conductivity gradients that results in an electric body force. This coupling results in an electric body force in the bulk liquid, outside theelectric double layer , that can generate temporal, convective, and absolute flow instabilities. Electrokinetic flows with conductivity gradients become unstable when the electroviscous stretching and folding of conductivity interfaces grows faster than the dissipative effect of molecular diffusion.Since these flows are characterized by low velocities and small length scales the Reynolds number is below 0.01 and the flow is laminar. The onset of instability in these flows is best described as an electric Rayleigh number.
For more information see:
* [http://microfluidics.asu.edu/eki.html Electrokinetic Instability Work in the Posner Research Lab]
* [http://microfluidics.stanford.edu/eki.htm Electrokinetic Instability work by Juan G. Santiago and coworkers]References
See also
*
Magnetohydrodynamic drive
*Magnetohydrodynamics
*Electrospray External links
* [http://blazelabs.com/l-intro.asp Blaze Labs Research - Introduction to EHD thrusters]
* [http://www.rmcybernetics.com/science/propulsion/ehdt.htm RMCybernetics - Electrohydrodynamic Propulsion and how to make an EHD Thruster at home]
* [http://www.mece.ualberta.ca/staff/Kostiuk/Kostiuk_index.htm Dr. Larry Kostiuk's website] .
* [http://www.sciencedaily.com/releases/2003/10/031020054036.htm Science-daily article about the discovery] .
* [http://news.bbc.co.uk/2/hi/technology/3201030.stm BBC article with graphics] .
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