Force on an asymmetric capacitor / Thomas B. Bahder and Chrisrian Fazi.

Format:

Book

Government document

Author/Creator:

Bahder, Thomas B. (Thomas Bazyli), 1955-

Contributor:

Fazi, Christian

U.S. Army Research Laboratory

Series:

ARL-TR (Aberdeen Proving Ground, Md.) ; 3005.

ARL-TR ; 3005

Language:

English

Subjects (All):

Capacitors.

Physical Description:

1 online resource (vi, 31 pages) : illustrations (chiefly color).

Place of Publication:

Adelphi, MD : Army Research Laboratory, [2003]

Summary:

When a high voltage (approx. 30 kV) is applied to a capacitor whose electrodes have different physical dimensions, the capacitor experiences a net force toward the smaller electrode (Biefeld-Brown effect). We have verified this effect by building four capacitors of different shapes. The effect may have applications to vehicle propulsion and dielectric pumps. We review the history of this effect briefly through the history of patents by Thomas Townsend Brown. At present, the physical basis for the Biefeld-Brown effect is not understood. The order of magnitude of the net force on the asymmetric capacitor is estimated assuming two different mechanisms of charge conduction between its electrodes: ballistic ionic wind and ionic drift. The calculations indicate that ionic wind is at least 3 orders of magnitude too small to explain the magnitude of the observed force on the capacitor. The ionic drift transport assumption leads to the correct order of magnitude for the force, however, it is difficult to see how ionic drift enters into the theory. Finally, we present a detailed thermodynamic treatment of the net force on an asymmetric capacitor. In the future, to understand this effect. a detailed theoretical model must be constructed that takes into account plasma effects: ionization of gas (or air) in the high electric field region. charge transport, and resulting dynamic forces on the electrodes. The next series of experiments should determine whether the effect occurs in vacuum, and a careful study should be carried out to determine the dependence of the observed force on gas pressure, gas species and applied voltage.

Notes:

Title from PDF title screen (viewed on Aug. 12, 2010).

"June 2003."

Includes bibliographical references (pages 24-25).

OCLC:

74251613

Access Restriction:

Approved for public release.