The nonlinear propagation of waves (specially solitary waves) in an ultra-relativistic degenerate dense plasma (containing ultra-relativistic degenerate electrons and positrons, cold, mobile, inertial ions, and negatively charged static dust) have been investigated by the reductive perturbation method. The linear dispersion relation and Korteweg de-Vries equation have been derived whose numerical solutions have been analyzed to identify the basic features of electrostatic solitary structures that may form in such a degenerate dense plasma. The existence of solitary structures has been also verified by employing the pseudo-potential method. The implications of our results in astrophysical compact objects have been briefly discussed.
Now-a-days, a great deal of interest has been grown in understanding of the basic properties of matter under extreme conditions (occurred by significant compression of the interstellar medium) [1-6], which are found in some interstellar compact objects. One of these extreme conditions is high density of degenerate matter in these compact objects which have ceased burning thermonuclear fuel, and thereby no longer generate thermal pressure. These interstellar compact objects are contracted significantly, and as a result, the density of their interiors becomes extremely high to provide non-thermal pressure via degenerate fermions/electron-positron pressure and particle-particle interaction. These compact objects support themselves against gravitational collapse by cold, degenerate fermions/electron-positron pressure, having their interiors close to a dense solid (ion lattice surrounded by degenerate electron-positrons, and possibly other heavy particles like dust) or close to a giant atomic nucleus (a mixture of interacting nucleus and electronpositron and possibly other heavy elementary particles and condensate or dust).
The degenerate fermion number density in such a compact object is so high that it follows the equation of state for degenerate fermions mathematically explained by Chandrasekhar [
Recently, a number of theoretical investigations have also been made of the nonlinear propagation of electrostatic waves in degenerate quantum plasma by a number of authors, e.g. Hass [
We consider inertialess ultra-relativistic degenerate electron-positron, cold, mobile, inertial ion fluid, and negatively charged static dust in our four component plasma system. Degenerate pressure of electron-positron fluid has been expressed in terms of density by using the ultra-relativistic limit. The nonlinear dynamics of the electrostatic perturbation mode in such a dusty e-p-i plasma system is described by the following equations.
where is the number density of the plasma species “s” (for electrons, positrons, and ions respectively) normalized by its equilibrium value, is the fluid speed (of the species s) normalized by the ion-acoustic speed, is the electrostatic wave potential normalized by (), x is the space variable normalized by , t is the time variable normalized by the ion plasma period
.
The constants and with
, , ().
We can express in terms of as with. Here, , , and are respectively the density ratio (), (), and ().
To examine electrostatic perturbations propagating in the ultra-relativistic degenerate dense plasma by analyzing the outgoing solutions of Equations (1)-(5), we first introduce the stretched coordinates [
where is the wave phase speed (with being angular frequency and being the wave number of the perturbation mode), and is a smallness parameter measuring the weakness of the dispersion (). We then expand, , , , and, in power series of:
and develop equations in various powers of. To the lowest order in, Equations (1)-(12) give
, , ,
, and.
We are interested in studying the nonlinear propagation of these dispersive dust ion-acoustic type electrostatic waves in a degenerate plasma. To the next higher order in, we obtain a set of equations
Now, combining Equations (13)-(17) we deduce a modified Korteweg-de Vries equation
where
For a moving frame moving with a speed, the stationary solitary wave solution of Equation (18) is
where the special stretched coordinates, , the potential, , and the width,.
It is obvious from Equation (19) and Equation (21) that the degenerate plasma under consideration supports compressive electrostatic solitary waves which are associated with a positive potential. It is observed from Equations (19)-(21) that the amplitude () of these solitary structures is directly proportional to square root of, i.e. proportional to and their width () is directly proportional to, i.e. to the square root of. It is also seen that the amplitude (width) increases (decreases) with the speed. The electrostatic solitary profiles are shown in Figures 1 and 2. The compressive dust ionacoustic solitary wave (DIASW), which can be treated as positive DIASW in a dusty e-p-i plasma system, is theoretically investigated.
The existence of DIASWs can be verified by using pseudo potential approach.To do so we first make all independent variables depend on a single variable by the transformation (where is the Mach number, solitary wave speed/). This transformation allows the steady state condition (), and the appropriate boundary conditions for localized perturbation (viz., , and at) allow us to write Equations (1)-(5) as
Now, substituting Equations (22)-(24) into Equation (25), multiplying the resulting equation by and applying the boundary condition, at, we obtain
where is given by
in which is the integration constant chosen in such a way that at. Equation (26) can be regarded as an “energy integral” [21,22] of an oscillating particle of unit mass, with pseudo-speed, pseudo-position, pseudotime, and pseudo-potential. This equation is valid for DIASWs in a dusty e-p-i plasma.
The expansion of around is
where, , and are given by
with, , and are expressed as
We now analyze Equations (27) and (28) with the help of Equations (29)-(31), and investigate the basic properties of SWs in a dusty e-p-i plasma. To study the possibility for the formation of the SWs, as well as their basic features (if they are formed), we first discuss the general conditions for the existence of the SWs. These conditions are
1), which are already satisfied by the equilibrium charge neutrality condition, and by the boundary condition chosen to obtain the value of the integration constant ().
2), which will be satisfied if
where is the critical Mach number.
3), which will be satisfied if
where is the amplitude of SWs.
4) for positive SWs (by positive SWs we mean compressive SWs, i.e. SWs with positive potential), for negative SWs (by negative SWs we mean rarefactive SWs, i.e. SWs with negative potential), and for DLs
which will be satisfied if
Conditions 1)-3) must be satisfied for SWs. However, in addition of these three, the first (second) of 4) is required only for positive (negative) SWs. Therefore, the minimum (critical) value of M for existence of SWs is determined by Equation (35). Hence the final condition reduces to
Now, using Equations (36) and (38), one can finally obtain
It is obvious from condition 2) that. Therefore, polarity of the nonlinear potential structures (SWs) depend on the polarity of. Thus, will give the boundaries separating the parametric regimes for the positive and negative SWs.
The solutions of Equation (39) for low speed DIA waves is plotted for and (in
The solitary profile from the solution of K-dV equation includes compressive SWs, i.e. SWs with positive potential (shown in
To summarize, we have investigated electrostatic solitary waves in an ultra-relativistic degenerate dense plasma, which is relevant to interstellar spherical compact objects like white dwarfs. The degenerate dense plasma is found to support both positive and negative solitary structures whose basic features (amplitude, width, speed, etc.) depend only on the plasma number density. It has been shown here that the amplitude, width, and speed increase with the increase of the plasma number density, but the electrostatic potential is negative. We finally hope that our present investigation will be useful for understanding the basic features of the localized electrostatic disturbances in an ultra-relativistic ultra-cold degenerate dense dusty plasma which is found in some astrophysical objects, (e.g. white dwarf stars, neutron stars, etc.) Thus the model we have considered in our present investigation (a dusty e-p-i plasma) supports the nonlinear propagation of dust-ion-acoustic solitary waves in extreme conditions for ultra-relativistic limit of density of plasma particles, which are found in many interstellar compact objects.
The Third World Academy of Science (TWAS) Research Grant for the research equipment are gratefully acknowledged (by M. S. Zobaer and A. A. Mamun).