Dispersion Relation of Stratified Electrothermal Instability in Warm, Dense, Tamped Aluminum-6061 with Current in a Skin Layer

Dispersion Relation of Stratified Electrothermal Instability in Warm, Dense, Tamped Aluminum-6061 with Current in a Skin Layer

The dispersion relation of the stratified electrothermal instability (ETI) has been measured on the surface of aluminum-6061 rods pulsed with rapidly rising lineal current density ( 3\times 10^{15} A m-1s-1 for 70 ns). The 500-\mu \mathrm{m} rod radius was much larger than the electrical skin depth....

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Bibliographic Details
Published in:2018 IEEE International Conference on Plasma Science (ICOPS) p. 1
Main Authors: Bauer, B.S., Hutchinson, T.M., Fuelling, S., Awe, T.J., Yu, E.P., Yelton, W.G., Yates, K.C.
Format: Conference Proceeding
Language:English
Published: IEEE 24-06-2018
Subjects:
Aluminum
Laboratories
Perturbation methods
Plasmas
Security
Skin
Surface waves
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Summary:The dispersion relation of the stratified electrothermal instability (ETI) has been measured on the surface of aluminum-6061 rods pulsed with rapidly rising lineal current density ( 3\times 10^{15} A m-1s-1 for 70 ns). The 500-\mu \mathrm{m} rod radius was much larger than the electrical skin depth. A transparent, 70-\mu \mathrm{m} . -thick, Parylene-N [poly(p-xylylene) ({}_{8}\text{CH}_{8})_{n} ] coating tamped the aluminum expansion and suppressed surface plasma. This enabled persistent observation, with time-resolved microscopy ( 3-\mu \mathrm{m} resolution, 2-13 ns gate), of discrete azimuthally-correlated stratified emission structures perpendicular to the current. Intensified CCD images of the surface were converted to temperature maps via radiometric calculations, assuming blackbody emission. Fourier analysis of these maps indicates the strata are comprised of temperature perturbations that grow exponentially at the rate \begin{equation*}\gamma(k)=0.06\text{ns}^{-1}-(0.4\text{ns}^{-1}\mu \mathrm{m}^{2}\text{rad}^{-2})k^{2},\end{equation*} where k < 0.4\mu \mathrm{m}/\text{rad} is the perturbation axial wavenumber. The aluminum was in the warm dense matter state, with density ~ 1 g/cm3 and temperature ~ 7,000 K.
ISSN:2576-7208
DOI:10.1109/ICOPS35962.2018.9575987