Title :
Instabilities in inhomogeneous complex plasma
Author :
Vaulina, O.S. ; Samarian, A.A. ; James, B.W. ; Vladimirov, S.V. ; Cramer, N.F.
Author_Institution :
Inst. for High Energy Densities, Moscow, Russia
Abstract :
Summary form only given, as follows. Problems associated with the formation and growth of instabilities in dissipative systems of interacting particles are under discussion in the varied fields of science (plasma physics, molecular biophysics, hydrodynamics etc.). A good experimental model for a study of instabilities in such is a dusty plasma. Dusty plasma consists of electrons, ions, neutral gas molecules and micron size charged dust particles. Usually the dust particles achieve electrostatic equilibrium with respect to the plasma by acquiring negative charge. This charge is not fixed but is coupled self-consistently to the surrounding plasma parameters. For this reason, new instabilities can develop in dusty plasma, leading to different self-exited dynamic phenomena observed in dust structures. A novel type of instability in inhomogeneous dusty plasma is considered. It is shown that spatial particle charge variation, which can occur due to an inhomogeneity of the bulk plasma surrounding the dust cloud, for example, due to the gradients of concentration n/sub e(i)/ or temperature T/sub e(i)/ of electrons (ions), provides an effective mechanism to excite motion of the dust. The results of numerical simulation of a dust plasma system with a spatial charge gradient and experimental observation of instabilities in a RF-discharge plasma are presented. Numerical simulations of the grain systems in the external electric and gravity fields were carried out using molecular dynamics method. Conditions suitable for observing various self-excited motions (vortices, oscillations and convection motion) of dust particles in the RF-glow discharge are discussed.
Keywords :
dusty plasmas; glow discharges; high-frequency discharges; molecular dynamics method; numerical analysis; plasma density; plasma deposition; plasma diagnostics; plasma flow; plasma instability; plasma oscillations; plasma simulation; plasma temperature; plasma transport processes; vortices; RF-discharge plasma; RF-glow discharge; bulk plasma; charged dust particles; concentration; convection motion; dissipative systems; dust cloud; dust motion; dust particles; dust plasma system; dust structures; dusty plasma; electrons; electrostatic equilibrium; external electric fields; external gravity fields; grain systems; inhomogencous dusty plasma; inhomogeneity; inhomogeneous complex plasma; instabilities; instabilities formation; instabilities growth; instability; interacting particles; ions; micron size charged dust particles; molecular dynamics method; negative charge; neutral gas molecules; numerical simulation; numerical simulations; oscillations; self-excited motions; self-exited dynamic phenomena; spatial charge gradient; spatial particle charge variation; surrounding plasma parameters; temperature; vortices; Dusty plasma; Electrons; Hydrodynamics; Molecular biophysics; Nonuniform electric fields; Nuclear and plasma sciences; Numerical simulation; Physics; Plasma simulation; Plasma temperature;
Conference_Titel :
Pulsed Power Plasma Science, 2001. IEEE Conference Record - Abstracts
Conference_Location :
Las Vegas, NV, USA
Print_ISBN :
0-7803-7141-0
DOI :
10.1109/PPPS.2001.961054
