Abstract:
The full kinetic dispersion relation for the Geodesic acoustic modes (GAMs) including
diamagnetic effects due to inhomogeneous plasma density and temperature is derived by using
the drift kinetic theory. The fluid model including the effects of ion parallel viscosity (pressure
anisotropy) is also presented that allows to recover exactly the adiabatic index obtained in kinetic
theory. We show that diamagnetic effects lead to the positive up-shift of the GAM frequency and
appearance of the second (lower frequency) branch related to the drift frequency. The latter is a
result of modification of the degenerate (zero frequency) zonal flow branch which acquires a
finite frequency or becomes unstable in regions of high temperature gradients. By using the full
electromagnetic drift kinetic equations for electrons and ions, the general dispersion relation for
geodesic acoustic modes (GAMs) is derived incorporating the electromagnetic effects. It is
shown that m=1 harmonic of the GAM mode has a finite electromagnetic component. The
electromagnetic corrections appear for finite values of the radial wave numbers and modify the
GAM frequency. The effects of plasma pressure βe, the safety factor q and the temperature ratio τ
on GAM dispersion are analyzed. Using the quantum hydrodynamical model of plasmas, the
stability analysis of self-gravitational electrostatic drift waves for a streaming non-uniform
quantum dusty magneto-plasma is presented. For two different frequency domains i.e.,
Ω0d<<ω<Ω0i (unmagnetized dust) and ω<< Ω0d < Ω0i (magnetized dust), we simplify the general
dispersion relation for self-gravitational electrostatic drift waves which incorporates the effects
of density inhomogeneity ∇n0α, streaming velocity v0α due to magnetic field inhomogeneity ∇B0,
Bohm potential and the Fermi degenerate pressure. For the unmagnetized case, the drift waves
may become unstable under appropriate conditions giving rise to Jeans instability. The modified
threshold condition is also determined for instability by using the intersection method for solving
the cubic equation. We note that the inhomogeneity in magnetic field (equilibrium density)
through streaming velocity (diamagnetic drift velocity) suppress the Jeans instability depending
upon the characteristic scale length of these inhomogeneities. On the other hand, the dust-lower-
hybrid wave and the quantum mechanical effects of electrons tend to reduce the growth rate as
expected. A number of special cases are also discussed.