Results 251 to 260 of about 112,080 (311)

Synergetic properties of advanced materials for high-power and high-temperature applications. [PDF]

Discov Nano
Mengesha WG, Nagessar K.
europepmc   +1 more source

Snell-corrected electric parameter scaling for 2-D FDTD dispersion reduction in layered tissues. [PDF]

Biomed Opt Express
Gasmelseed A.
europepmc   +1 more source

The thermal conductivity and electrical resistivity of electrically conductive fabrics

, 1970
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Electric conductivity in microemulsions

Journal of Chemical Physics, 1993
Microemulsions exhibit a rather sudden change of electric conductivity upon varying either composition at fixed temperature, or temperature at fixed mean composition. In literature this has been interpreted as a percolationlike process. In this paper we question this interpretation, and suggest instead that the change of conductivity is caused by a ...
M Kahlweit, G Busse, Kahlweit M
exaly   +3 more sources

Conductive mechanisms in electrical conductive adhesives with isotropical electrical conductivity

2011 IEEE 17th International Symposium for Design and Technology in Electronic Packaging (SIITME), 2011
Electrical conductivity of electrically conductive adhesives is controlled with three mechanisms. These mechanisms are described — a phonon-electron interaction, a constriction mechanism and a tunnel mechanism. If the phonon-electron and constriction mechanisms dominate; the temperature dependence of resistivity is positive and linear, and the ...
Pavel Mach, Jakub Cinert
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Electrical Conduction in Chlorpromazine

Nature, 1965
WE wish to report some further results on the electrical properties of 10-dimethylaminopropyl-2-chlorophenothiazine, commonly known as chlorpromazine. Previous work1 indicated this substance to be a semi-conductor with an activation energy of 2.1 eV and a d.c. resistivity of 1.3 × 1011 ohm-cm at 16° C.
F, Gutman, H, Keyzer
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Electrical Conductivity of Graphite

Journal of the Physical Society of Japan, 1963
Theoretical calculations are given for the electrical conductivity of graphite in the hexagonal layer planes. The resistivity increases with temperatures as T 1.2 between 25°K and 77°K. In the long wave-length limit, the lattice vibrations of graphite are approximatly grouped into two modes, polarization being in the layer plane in model 1, and ...
Sugihara, Ko, Sato, Hisanao
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