Coulomb fission of a charged dust cloud in an afterglow plasma*

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Presentation transcript:

Coulomb fission of a charged dust cloud in an afterglow plasma* T07.00001 APS DPP 2015 November 16-20 Savannah, GA Coulomb fission of a charged dust cloud in an afterglow plasma* R. L. Merlino and J. K. Meyer Department of Physics and Astronomy The University of Iowa, Iowa City, IA 52242 *Supported by DOE and NSF

Coulomb explosion PLASMA DUST A cloud of negatively charged dust particles suspended in a plasma which provides charge, confinement, and shielding Turn the plasma off The plasma decays on a time scale faster that the charging time of the dust Now have cloud of negative particles with No confinement No shielding Result  Coulomb explosion ! PLASMA DUST

Estimated acceleration  few g Coulomb explosion of dust particles confined in an anode glow discharge t = 0 t = 2/30 s t = 1/30 s 16 mm Estimated acceleration  few g In agreement with MD simulations of Saxena, Avinash, and Sen, Phys. Plasmas 19, 093706, 2012.

Motivation Study how a finite system responds to a large excess charge Study behavior of a dusty plasma in a plasma afterglow What is the residual charge on the dust Depending on conditions interaction can be Coulomb or Yukawa What are the possible topologies of a disintegrating charge cluster: large fragments, small fragments, or individual particles? Analysis of cluster disintegration may reveal collective effects Connections to Coulomb explosion and fission of atomic clusters under high intensity laser irradiation Connections to disintegration of charged liquid droplets and the Rayleigh criterion for breakup: Q > 8p(eog a3)1/2, g = surface tension.

Experimental set-up DC glow discharge in argon at p  0.1 – 0.2 Torr 1 micron diameter spherical silica particles Conical mesh used to trap a secondary dust cloud

Three fragmentation channels were observed Blow-off: the outer layer of the cloud is suddenly shed Expansion: the entire cloud expands in 3D under Coulomb repulsion Fission: the cloud splits into 2 pieces Relevant issues: Each cloud fragmentation event results in the destruction of the cloud The plasma and dust cloud must be reformed for each new experiment Each dust cloud is different in size, shape, and density The observed fragmentation channel may be strongly affected by initial conditions.

Blow-off 20 x 24 mm Expansion 15 x 17 mm Fission 18 x 26 mm

Single-frame images of dust cloud fission

Dust density profiles of a fissioning cloud

Position vs. time of maximum density in lower cloud The position of the lower cloud ~ t2 over the first 2 ms, with an estimated acceleration  103 m/s2 From t > 6 ms, the lower cloud speed is reduced to a value consistent with free-fall with neutral drag This reduction in the speed of the cloud is likely due to the reduction in the dust charge

SUMMARY We have studied how clouds of charged dust particles respond when the plasma that they are immersed in is suddenly turned off. Three types of cloud evolutions have been observed Blow-off --- the outer layer of the cloud is rapidly shed Expansion --- the cloud expands uniformly Fission --- the cloud fragments into two pieces MD simulations are being performed to identify the conditions that control how a charged dust cloud evolves under repulsive electrostatic forces