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ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS. / Mikhailov, A. A.; Stishkov, Yu K.

In: Magnetohydrodynamics, Vol. 13, No. 2, 01.01.1977, p. 193-197.

Research output: Contribution to journalArticlepeer-review

Harvard

Mikhailov, AA & Stishkov, YK 1977, 'ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS.', Magnetohydrodynamics, vol. 13, no. 2, pp. 193-197.

APA

Mikhailov, A. A., & Stishkov, Y. K. (1977). ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS. Magnetohydrodynamics, 13(2), 193-197.

Vancouver

Mikhailov AA, Stishkov YK. ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS. Magnetohydrodynamics. 1977 Jan 1;13(2):193-197.

Author

Mikhailov, A. A. ; Stishkov, Yu K. / ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS. In: Magnetohydrodynamics. 1977 ; Vol. 13, No. 2. pp. 193-197.

BibTeX

@article{e414fc26240748c4a73fa2314271dc2d,
title = "ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS.",
abstract = "In the region of developed EHD flows, the intense motion of the medium has a significant effect on current transport and convection currents may be considerably greater than ohmic conductivity currents. The electroconductive forces are collinear with the field-strength vector and are directed so as to reduce the cconductivity of the medium. The effect of electroconductive forces in nonpolar electrically insulating fluids is demonstrated in three examples. In the first two, the electric field is uniform and the effect of the dielectric component can be neglected. In the last example, the dielectrophoretic and Coulomb components are oppositely directed. In the first two, the effect of a uniform electric field on a region of heightened conductivity insulated from the electrodes is discussed; in the third, the electric wind from a point is considered.",
author = "Mikhailov, {A. A.} and Stishkov, {Yu K.}",
year = "1977",
month = jan,
day = "1",
language = "English",
volume = "13",
pages = "193--197",
journal = "Magnetohydrodynamics",
issn = "0024-998X",
publisher = "Издательство Латвийского университета",
number = "2",

}

RIS

TY - JOUR

T1 - ELECTROHYDRODYNAMIC FLOWS IN FLUID DIELECTRICS.

AU - Mikhailov, A. A.

AU - Stishkov, Yu K.

PY - 1977/1/1

Y1 - 1977/1/1

N2 - In the region of developed EHD flows, the intense motion of the medium has a significant effect on current transport and convection currents may be considerably greater than ohmic conductivity currents. The electroconductive forces are collinear with the field-strength vector and are directed so as to reduce the cconductivity of the medium. The effect of electroconductive forces in nonpolar electrically insulating fluids is demonstrated in three examples. In the first two, the electric field is uniform and the effect of the dielectric component can be neglected. In the last example, the dielectrophoretic and Coulomb components are oppositely directed. In the first two, the effect of a uniform electric field on a region of heightened conductivity insulated from the electrodes is discussed; in the third, the electric wind from a point is considered.

AB - In the region of developed EHD flows, the intense motion of the medium has a significant effect on current transport and convection currents may be considerably greater than ohmic conductivity currents. The electroconductive forces are collinear with the field-strength vector and are directed so as to reduce the cconductivity of the medium. The effect of electroconductive forces in nonpolar electrically insulating fluids is demonstrated in three examples. In the first two, the electric field is uniform and the effect of the dielectric component can be neglected. In the last example, the dielectrophoretic and Coulomb components are oppositely directed. In the first two, the effect of a uniform electric field on a region of heightened conductivity insulated from the electrodes is discussed; in the third, the electric wind from a point is considered.

UR - http://www.scopus.com/inward/record.url?scp=0017475715&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:0017475715

VL - 13

SP - 193

EP - 197

JO - Magnetohydrodynamics

JF - Magnetohydrodynamics

SN - 0024-998X

IS - 2

ER -

ID: 40623651