Research Article  Open Access
P. K. Karmakar, "Nonlinear Gravitoelectrostatic Sheath Fluctuation in Solar Plasma", Physics Research International, vol. 2011, Article ID 103893, 10 pages, 2011. https://doi.org/10.1155/2011/103893
Nonlinear Gravitoelectrostatic Sheath Fluctuation in Solar Plasma
Abstract
The nonlinear normal mode dynamics is likely to be modified due to nonlinear, dissipative, and dispersive mechanisms in solar plasma system. Here we apply a plasmabased gravitoelectrostatic sheath (GES) model for the steadystate description of the nonlinear normal mode behavior of the gravitoacoustic wave in fieldfree quasineutral solar plasma. The plasmaboundary wall interaction process is considered in global hydrodynamical homogeneous equilibrium under spherical geometry approximation idealistically. Accordingly, a unique form of KdVBurger (KdVB) equation in the lowestorder perturbed GES potential is methodologically obtained by standard perturbation technique. This equation is both analytically and numerically found to yield the GES nonlinear eigenmodes in the form of shocklike structures. The shock amplitudes are determined (~0.01 V) at the solar surface and beyond at 1 AU as well. Analytical and numerical calculations are in good agreement. The obtained results are compared with those of others. Possible results, discussions, and main conclusions relevant to astrophysical context are presented.
1. Introduction
The Sun, like stars and ambient atmospheres, has exploratively been an interesting area of study for different authors by applying different physical model approaches and observational techniques for years [1–13]. Some of the basic electromagnetic properties of such stars and stellar atmospheres have been reported in hydrostatic equilibrium of the constituent ionized gas [1, 2]. The steady supersonic radial outflow of the ionized gas from the Sun (or star), called solar wind (or stellar wind), has been found to support various nonlinear eigenmodes [4]. Such nonlinear eigenmodes are usually solitons, shocks, and so forth [4, 9–17] found to exist almost everywhere in space including dustcontaminated space plasma [14, 15]. Nonlinear stability analyses of the Sun and its atmosphere have, however, been boldly carried out by many authors applying magnetohydrodynamic (MHD) equilibrium configurations [9–13] by means of standard multiple scaling techniques. Nevertheless the effects of space charge, plasmaboundary wall interaction, and sheath formation mechanism have hardly been addressed in such model stability analyses on the Sun and its atmosphere reported so far.
We are here going to propose a nonlinear stability analysis on the Sun on the basis of the plasmabased gravitoelectrostatic sheath (GES) model [3]. According to this GES model analysis, the solar plasma system divides into two parts: the Sun which is the subsonic solar interior plasma (SIP) on bounded scale and the supersonic or hypersonic solar wind plasma (SWP) on unbounded scale. The solar surface boundary (SSB) couples the SIP (Sun) with the SWP through plasmaboundary wall interaction processes in a selfgravitating equilibrium configuration of hydrodynamic type. The SSB behaves like a spherical electrical grid negatively biased with the equilibrium GES potential ( kV) through the process of the self gravitoelectrostatic interaction. Henceforth, for coupled structural information, the terms “GES fluctuation”, “SIP fluctuation”, “GES perturbation,” and “SIP perturbation” will be synonymously used to describe the “nonlinear GES stability on the bounded SIP scale” in this investigation of solar plasma fluctuation dynamics.
The main motivation of this paper is to examine whether the solar plasma system, as a natural plasma laboratory, can support any nonlinear characteristic eigenmode through the GES model with plasmaboundary interaction taken into account. Spacecraft probes and Earthorbiting satellites have also technically detected many widescale nonlinear mode features [4, 12, 13] like nonpropagating pressurebalance structures, collisionless shocks, turbulencedriven instability, soliton, and so forth. These have particularly been applied to probe plasma kinetic effects in the form of collective wave activities in some important parameter regimes [4] experimentally inaccessible to laboratories due to the complex nature of the dynamics of the solar wind particles. Thus a theoretical model analysis is highly needed in support of the description of these experimental observations.
A distinct set of nonautonomous selfconsistently coupled nonlinear dynamical eigenvalue equations in the defined astrophysical scales of space and time configuration is accordingly developed. In view of that, a unique form of KdVBurger (KdVB) equation [9–11, 14, 15] is methodologically derived on the SIP scale in terms of the lowest order GES potential fluctuation. It is then studied analytically as well as numerically as an initial value problem. The gravitoelectrostatic features are asymptotically examined even on the SWP to explore some new observations on the nonlinear eigenmodes of the GES. Apart from the “Introduction” part described in Section 1 above, this paper is structurally organized in a usual simple format as follows. Section 2, as usual, contains physical model of the solar plasma system under investigation. Section 3 contains mathematical formulation and required derived analytical equations and expressions. Section 4 shows the obtained results and discussions in three subsections. Sections 4.1, 4.2, and 4.3 give the analytical, numerical, and comparative results, respectively. Lastly and most importantly, Section 5 depicts the main conclusions of scientific interest and astrophysical applicability.
2. Solar Plasma Model
A very simplified ideal solar plasma fluid model is adopted to study the GES model stability under a global hydrodynamic type of homogeneous equilibrium configuration. Gravitationally bounded quasineutral fieldfree plasma by a spherically symmetric surface boundary of nonrigid and nonphysical nature is considered. An estimated typical value ~10^{−20} of the ratio of the solar plasma Debye length and Jeans length of the total solar mass justifies the quasineutral behavior of the solar plasma on both the bounded and unbounded scales. A bulk nonisothermal uniform flow of solar plasma is assumed to preexist. For minimalism, we consider spherical symmetry of the selfgravitationally confined SIP mass distribution, because this helps to reduce the threedimensional problem of describing the GES into a simplified onedimensional problem in the radial direction since curvature effects are ignorable for small scale size of the fluctuations. Thus only a single radial degree of freedom is sufficient for describing the threedimensional SIP and, hence, the SWP in radial symmetry approximation. This is to elucidate that our plasmabased theory of the GES stability is quite simplified in the sense that it does not include any complicacy like the magnetic forces, nonlinear thermal forces and the role of interplanetary medium or any other difficulties like collisional, viscous processes, and so forth.
Applying the spherical capacitor charging model [3], the coulomb charge on the SSB comes out to be C. More on the basic electromagnetic properties of the Sun and its atmosphere could be understood from the electrical stellar models [1, 2]. Let us approximately take the mean rotational frequency of the SSB about the centre of the SIP system to be Hz. Applying the electrical model [2] of the Sun, the mean value of the strength of the solar magnetic field at the SSB in our model analysis is estimated as T, which is negligibly small for producing any significant effects on the dynamics of the SIP particles. Thus the effects of the magnetic field are not realized by the solar plasma particles due to the weak Lorentz force, which is now estimated to be N corresponding to an average subsonic flow speed cm s−1, and hence, neglected. It equally justifies the convective and circulation dynamics being neglected in our SIP model. Therefore our unmagnetized plasma approximation is well justified in our model configuration on the bounded SIP scale. The same, however, may not apply for the unbounded SWP scale description. This is because the Lorentz force for the SWP comes out to be N to a mean supersonic flow speed km s^{−1}, thereby showing that . ln addition, the effects of solar rotation, viscosity, nonthermal energy transport, and trapping of plasma particles are as well, for mathematical simplicity, neglected in our idealized plasmabased model approach for the SIP description.
The solar plasma is assumed to consist of a single component of Hydrogen ions and electrons. The thermal electrons are assumed to obey Maxwellian velocity distribution in an idealized situation. In reality, of course, deviations exist, and hence different kinds of exospheric models have already been proposed with special velocity distribution functions kinetically [4, 7, 8]. Again inertial ions are assumed to exhibit their full inertial response of dynamical evolution governed by fluid equations of quasihydrostatic equilibrium. This includes the ion fluid momentum equation as well as the ion continuity equation. The first describes the change in ion momentum under the action of the heliocentric gravitoelectrostatic field due to selfgravitational potential gradient and forces induced by thermal gas pressure gradient. The latter is considered as a gas dynamic analog of the solar plasma selfsimilarly flowing through a spherical chamber of radially varying crosssectional area with macroscopic bulk uniformity in accordance with the basic rule of idealistic fluid flux conservation.
3. Mathematical Formulation
The basic normalized (with all standard astrophysical quantities) autonomous set of nonlinear differential evolution equations with all the usual notations [1] constituting a closed hydrodynamical structure of the solar plasma system has already been developed in timestationary form. The same set of the basic structure equations defined in the gravitational scale of space and time is developed in nonautonomous form and enlisted as follows: Here , is the thermal electron temperature, and is the inertial ion temperature on the bounded SIP scale (each in eV). This should be mentioned that (4) is a nonplaner geometrical outcome of the generalized electrostatic Poisson’s equation with global quasineutrality approximation in a spherical symmetric distribution of the solar plasma with all the usual notations [1] given as Here denotes the SIP electron Debye length. For instant information, the solar parameters , and represent the equilibrium Mach number, solar selfgravity, and electrostatic potential, respectively. They are respectively normalized by plasma sound phase speed , solar freefall (heliocentric) selfgravity strength , and electron thermal potential . Moreover, the independent variables like time and position are normalized with Jeans time and Jeans length scales, respectively, as already carried out in our earlier publication [3] too.
In order to get a quantitative flavor for a typical value of K, for example, one can estimate the value of [3]. This implies that the size of the Debye scale length is quite smaller than that of the Jeans scale length of the solar plasma mass. Thus on the typical gravitational scale length of the inertially bounded solar plasma system, the limit becomes a realistic (physical) approximation. By virtue of this limiting scale condition the entire SIP extended up to the SSB and beyond obeys the plasma approximation of global quasineutrality, as from (5), in our defined selfgravitating solar plasma system justifiably.
Applying the usual standard methodology of reductive perturbation technique [14, 15] over the coupled set of (1)–(4), we want to derive a nonlinear dynamical equation in the lowestorder perturbed GES potential in the SIP scale. Methodologically, the independent variables are thus stretched directly as and . Thus in the newly defined space of stretched variables, the linear differential operators transform as , , and , where is the phase speed of the GES perturbation and is a smallness parameter characterizing the balanced strength of dispersion and nonlinearity. The dimensionless amplitude of the lowestorder fluctuations is usually given by this parameter ∈ [10, 11].
The nonlinearities in our might have directly come from the largescale dynamics (in space and time) through the harmonic generation involving fluid plasma convection, advection, dissipation, and so forth. These nonlinearities may contribute to the localization of waves and fluctuations leading to the formation of different types of nonlinear coherent structures like solitons, shocks, vortices, and so forth which have both theoretical as well as experimental importance [14]. The scale size of all the nonlinear fluctuations of current interest is assumed to be much shorter than all the characteristic mean free paths. These scaling analyses have, systematically, been derived under the conditions that the normalized fluctuations in the dependent solar plasma variables are of the same order within an order of magnitude in the astrophysical scale of space and time.
In order to study the GES stability of the present concern, the relevant solar physical variables are now perturbatively expanded around the respective welldefined GES equilibrium values as follows: We now substitute (6) into the basic governing (1)–(4). Equating the terms in various powers of from both sides of (1), one gets Similarly, equating the terms in various powers in from (2), one gets The orderbyorder analysis in various powers of from (3) similarly yields The same orderbyorder analysis in various powers in from (4) yields
We are involved in the dynamical study of the lowestorder GES potential fluctuation associated with the SIP system. Equation (8), therefore, is now approximately simplified into the following form: A little exercise with the substitution of (15) in (9) (under an approximation of equal rate of harmonic covariation) jointly gives Again spatially differentiating (13), one gets
Now coupling (16) and (17) dynamically with no variation of the equilibrium parameters, one gets easily the following modified form of KdVBurger (KdVB) equation [9–11, 14, 15] for the description of the nonlinear GES fluctuations in terms of as follows:
This is clear from (18) that the temporal part (1st term) and convective part (2nd term) have constant coefficients in a given plasma configuration bounded quasihydrostatically. The dispersive part arising due to the deviation from global plasma quasineutrality (3rd term) and dissipative part arising due to various internal loss processes (4th term), however, have variable coefficients. We are interested in timestationary structures of dynamical fluctuations, and hence, (18) is transformed into an ordinary differential equation (ODE) with the transformation so that the operational equivalence and hold good. Equation (18), therefore, with and gets transformed into a stationary form as where denotes the lowestorder fluctuation in the GES potential.
Equation (19) clearly shows the possibility for the existence of some shocklike structures (due to energy dissipation) in addition to solitonlike structures (due to energy dispersion). The first class of structures realistically arises when the effect of dissipation is significant in comparison with the joint effect of the nonlinearity and dispersion, whereas for the second class, the effect of dissipation is insignificant in comparison with that produced jointly by the nonlinearity and dispersion [14]. Being of nonlinear type, the exact solution of (19) is difficult without any asymptotic approximation. The approximate solutions are obtained analytically by the method of integration with some boundary conditions like , , at as done by others [14]. The explicit form of the analytical solution (traveling wave) of (19) with all the usual notations is derived and presented as follows:
Equation (20), in fact, represents the asymptotic form of a monotonic shock structure (laminar type) with shock speed , shock amplitude , and shock front thickness . The fundamental difference of the solution (20) with those obtained analytically by others [14] is that the present solution represent shocks in the perturbed GES potential in the selfgravitating hydrodynamic SIP with plasmaboundary interaction taken into account. The other reported solutions [14], on the other hand, represents shocks in the perturbed electrostatic potential and density in dusty plasma in hydrostatic equilibrium, but in the absence of plasmaboundary wall interaction processes, selfgravity, and gravitoelectrostatic coupling effects. This, interestingly, is noticed here that the shock width of (20) here is a function of the independent position coordinate alone in the defined selfgravitating solar plasma configuration. Eventually, this impulsive character of the SIP blast wave is realistically justifiable due to infinite thermal pressure at the core of the Sun [3] generated by the effect of the strong selfgravitational collapse leading to thermonuclear fusion responsible for tremendous amount of energy production.
Equation (19) is furthermore numerically solved (by RungeKutta IV method) to get a detailed picture of the basic features of the GES fluctuations on astrophysical scale under different realistic initial values of the relevant solar physical variables. These realistic initial values are analytically arrived at as a natural outcome of the nonlinear dynamical stability analyses around fixed points, as carried out in our earlier work [3], over the coupled dynamical equations of the twolayer GES model description.
4. Results and Discussions
4.1. Analytical Results
A theoretical model analysis is carried out to study the GES fluctuation in a simplified fieldfree quasineutral solar plasma model in quasihydrostatic type of homogeneous equilibrium configuration. A distinct set of nonautonomous selfconsistently coupled nonlinear dynamical eigenvalue equations in a defined astrophysical space and time configuration are developed. Applying the standard methodology of reductive perturbation technique over the defined GES equilibrium [3], a modified form of KdVBurger (KdVB) equation in terms of the lowestorder perturbed GES potential is obtained. An explicit form of the approximate analytical solution (shock family) only is derived with the help of conventional method of integration [14] by imposing asymptotic boundary conditions. Similar analytical results exist in the literature [14, 15], but in terms of shocks in the perturbed electrostatic potential and density in dustcontaminated plasma in hydrostatic equilibrium in absence of the effects of all plasmaboundary wall interaction, selfgravity, and gravitoelectrostatic coupling mechanisms as already mentioned above in the previous section.
Let us now estimate the physical values of the main shock characterization parameters represented by (20) at the SSB. At the SSB, , and [3]. Typically, the smallness parameter is [10] for solar plasma atmosphere. Now for and , we can analytically estimate the physical value of the GES potential shock amplitude (= volts, or statvolts) and shock front thickness ( m, or cm). Thus gravitoelectrostatic shocks in the SIP system carry relatively lower energy of the GESinduced mode.
The reductive perturbation method is, however, not very popular as a mathematically rigorous perturbation method, even conditionally. It, nevertheless, is a convenient, approximate, and easy way to produce certain mathematically interesting paradigm of nonlinear equations. By the free ordering, we may get almost any explicit form of results as expected. In particular, the ordering required to get, for example, a shocklike solution is now known. Numerical solutions will subsequently show that there are many other shocklike structures that do not satisfy the “required ordering”. In fact, although shocks are frequently found experimentally, so far a shock that satisfies the KdVB ordering has never been found, whether in neutral fluid, lattice, or plasma. Thus, analytically, it provides a new mathematical stimulus scope for future interest to derive analytical results with greater accuracy with newer mathematical techniques so as to get more detailed picture of the selfgravitational fluctuations like in the Sun.
4.2. Numerical Results
Our theoretical GES model analysis shows that the solar plasma system supports shock formation governed by KdVB (19). This is again integrated numerically too so as to get some numerical profiles for different initial values on a more detailed grip. The main features of our observations based on our numerical analyses may be discussed as follows. Figure 1(a) shows the profile on the SIP scale with , , and . The various lines correspond to Case 1: , Case 2: , Case 3: , and Case 4: , respectively. Figure 1(b) similarly depicts the same, but on the SWP scale. It is clear that the GES perturbation excited on the SIP scale gets propagated even at and up to an asymptotically large distance due to space charge polarization effects boosted up by the supersonic SWP flow. The fluctuation assumes various nonlinear forms of shock family sensitive to input initial position values relative to the heliocentric origin. The amplitude is found to vary from to at the SSB , the SWP base. It is again on the order of at 1 AU approximately. All these observations are relative to the unperturbed GES potential value at the SSB. The SSB is already reported to act as a spherically symmetric electrical grid which is gravitoelectrostatically negatively biased with a normalized value of the equilibrium GES potential ~ −1 (= −1.00 kV) [3]. The SWP flow dynamics is the natural outcome of the solar plasma leakage process through this electrical grid.
(a)
(b)
Again Figure 2(a) similarly depicts the profile on the SIP scale with , and . The various lines are for Case (1) , Case (2) , Case (3) , and Case (4) , respectively. Figure 2(b) gives the same, but on the SWP scale. It is clear that, as in Figure 1, different shocklike structures arise from different flow velocities with amplitude lying on the order of on both the SIP and SWP scales.
(a)
(b)
Lastly, Figure 3(a) shows the profile on the SIP scale with , and . The various lines specify Case (1) , Case (2) , Case (3) , and Case (4) , respectively. Likewise, Figure 3(b) gives the same, but on the SWP scale. It is found that the amplitude varies from to in the SIP scale. Its order is the same even at 1 AU. This is interestingly in totality found numerically (Figures 1–3) that the GES potential fluctuation propagates as shocklike structures with amplitude at both the SSB and at 1 AU, approximately. Thus for a typical value of the smallness parameter [10] for solar plasma configuration, the physical value of the GES potential shock amplitude can throughout the numerical analyses be calculated as volts. In all the cases, the amplitude is usually found to go more and more negative near the heliocentre due to strong selfgravitational effects, acting even on the plasma thermal electrons and thereby, tending to prevent them to escape through solar selfgravitational potential barrier. The reversibility of the magnitudes of the GES shocklike structures from negative to positive values is ascribed due to the solar plasma leakage process through the SSB grid.
(a)
(b)
4.3. Comparative Results
This has been recognized years ago that the compressional plasma in the solar atmosphere is a perfect medium for magnetohydrodynamic (MHD) waves. Applying the MHD model analyses [9–11, 16, 17], several authors have investigated on the corresponding nonlinear eigenmodes in the compressional solar plasma in presence of magnetic field. Some of the important distinctions between our GES stability analysis and MHD stability analyses on the solar plasma fluctuation dynamics reported so far in the literature are worth mentioning here. The following tabulation, Table 1, shows the main distinctions between them.

We scientifically admit that the neglect of collisional dissipations and deviation from Maxwellian velocity distributions of the plasma particles is not quite realistic. But our GES stability analyses even under some simplified and idealized approximations may provide quite interesting results for the solar physics community. The main points based on our analyses are summarized as follows.(1)The GES fluctuations appear in the form of various nonlinear structures (of shockfamily eigenmodes) governed by a new analytic form of KdVBurger (KdVB) equation. Here the terminology “new analytic form” refers to the appearance of the new type of characteristic coefficients in the dispersive and dissipative terms in it. (2)The influence and presence of such eigenmodes are also experienced asymptotically even in the SWP scale. The structural modification here is due to the background initial conditions under which being excited. Such blast wave structures arise mainly due to violent disturbances of selfgravitational type. Their front thickness may, however, be a consequence of the homogeneous balance between selfgravitating solar plasma nonlinear compressibility and dissipative mechanisms like viscosity, heat conduction, and so forth. Similar observations in the Sun have also been reported by MHDcommunity under HallMHD approximation [9–11] in terms of the lowestorder perturbed solar density fluctuation. In addition, such structures have also been experimentally observed and reported in a dustcontaminated plasma system [14, 15] with different grain population density in both oscillatory as well as laminar forms, but in absence of gravitoelectrostatic effects.(3)Selfgravity of the SIP mass distribution is normally found to have a tendency to depress (due to dissipation and dispersion) the nonlinear structures in the interior (subsonic SIP flow) and steepens (due to nonlinearity) them in the exterior (supersonic SWP flow) in our twoscale GES stability analyses.(4)Last but not least, the fluctuations become almost uniform at an asymptotically large distance relative to the heliocentre. This physically means that the SWP flow is a uniform one asymptotically, and net electric current, contributed jointly by solar thermal electrons and inertial ions, will remain conserved (divergencefree current density in a steadystate description) which is in good agreement with the already reported results [18].
This analysis, moreover, is carried out in a homogeneous kind of fieldfree quasihydrostatic equilibrium configuration under quasineutral plasma approximation. However, even in spite of these limitations, it may perhaps be useful for further investigation of dynamical stability on a nonlinearly coupled system of the SIP and SWP as an interplayed flow dynamics of heliocentric origin in presence of all the possible realistic agencies [16, 17] like collision, viscosity, and so forth. This is speculated that the normal mode behaviors of the global SSB oscillations could also be analyzed in terms of both the local as well as global gravitoelectrostatic plasma sheathinduced oscillations with such techniques. Additionally, gaseous phase of the solar plasma is reported to contain solid phase of dust matter [19]. In the SWP scale of uniform flow, application of the inertiainduced acoustic excitation mechanism [20] may further be carried out for further stability analyses. The basic principles of the nonlinear pulsational mode [21] of the selfgravitational collapse model of charged dust clouds by applying the presented methodology may be another important future application in the selfgravitating solar plasma system.
5. Conclusions
The dynamical stability of the GES model, although simplified through idealistic approximations, is analyzed in both analytical and numerical forms with standard perturbation formalism. It provides an idea into the interconnection between the SIP (Sun) stability in terms of the lowestorder GES fluctuation appearing as various nonlinear structures (shock like) and their asymptotic propagation in the SWP scale as an integrated model approach. This is conjectured that the fluctuations are jointly governed by a new form of KdVBurger type of nonlinear evolution equation having some characteristic model coefficients. Both analytical and numerical solutions are in qualitative and quantitative agreement. The main conclusions of scientific interest drawn from our present contribution are summarized as follows.(1)Nonlinear fluctuations of the GES in the SIP scale are governed by a KdVBurger (KdVB) type of equation with characteristic coefficients dependent on the solar plasma GES model.(2)Different forms of nonlinear eigenmodes exist in the SIP scale in different situations. Their presence, pretriggered strongly due to selfgravity on the SIP scale origin, is also experienced at asymptotically large distances beyond the SSB. It goes in qualitative conformity with those reported with different methodologies [2, 12, 13].(3)The structures are contributed mainly due to gravitoelectrostatically coupled selfgravity fluctuation of the solar plasma inertial ions under an integrated interplay of diverse nonlinear (hydrodynamic origin) and dispersive (selfgravitational origin) effects in the solar plasma system in presence of some internal dissipation.(4)The SIP is found to be more unstable (more fluctuation gradient) than the SWP (less fluctuation gradient) asymptotically. This is because of the GES fluctuation in presence of strong selfgravity in the bounded SIP scale and weak external gravity in the unbounded SWP scale.(5)Our twoscale theory of the GES is found to give twoscale dynamical variation of the GES stability as a gravitoelectrostatically coupled system of the SIP (subsonic flow) and the SWP (supersonic flow) through the interfacial SSB.
Finally and additionally, the modified GES mode kinetics as a selfgravitationally triggered instability in an intermixed state of the gaseous phase of plasma and solid phase of dust grainlike impurity ions (DGIIs), by using a dissipative multifluid colloidal or dusty plasma model with dust scale size distribution power law taken into account, may be another interesting investigation to study DGIIbehavior in an SWPlike realistic situation on a global scale. This is because the interplay between gravitational and electrostatic forces in the dynamics of such grains is responsible for many interesting phenomena in the terrestrial and solar environment (like rings of Saturn and Jupiter, satellites’ spoke formation, etc.). It eventually may have some useful characteristic implications of acoustic spectroscopy ([20] and references therein) as well on the basis of dispersion wave analyses to be characterized with different scalesized inertial species (DGIIs) in different realistic astrophysical conditions. The mathematical methodology adopted may also be extensively applicable to other types of nonlinear waves, wherever all being considered as derivatives of shocks in presence of nonlinearity, dispersion, and dissipation, by applying kinetic exospheric model approaches [7, 8] with the more realistic SWP exobases taken into concern. These mathematical analyses may be extended for further investigation of fluctuation and stability with more realistic assumptions like grain rotations, spatial inhomogeneities, different gradient forces, and so forth, taken into account in other astrophysical and space environments. These calculations, although tentative for any concrete application to any sharply specified stellar formation mechanism, may be widely useful in the study of fluctuationinduced dynamics with electrostatic charge fluctuation of dust grains in astrophysical environment of dusty plasmas in the complex form of selfgravitationally collapsing dust cloud [21].
Acknowledgments
The valuable comments, specific remarks, and precise suggestions by an anonymous referee, to refine the prerevised original paper into the present postrevised improved form, are very gratefully acknowledged. Moreover, the financial support received from the University Grants Commission of New Delhi (India), through the research project with Grant F. no. 34503/2008 (SR), is also thankfully recognized for carrying out this work.
References
 S. Rosseland, “Electrical state of a Star,” Monthly Notices of the Royal Astronomical Society, vol. 84, pp. 308–317, 1924. View at: Google Scholar
 R. Gunn, “The electrical state of the sun,” Physical Review, vol. 37, no. 8, pp. 983–989, 1931. View at: Publisher Site  Google Scholar
 C. B. Dwivedi, P. K. Karmakar, and S. C. Tripathy, “A gravitoelectrostatic sheath model for surface origin of subsonic solar wind plasma,” Astrophysical Journal, vol. 663, no. 2, pp. 1340–1353, 2007. View at: Publisher Site  Google Scholar
 S. R. Cranmer, “Coronal holes and the highspeed solar wind,” Space Science Reviews, vol. 101, no. 34, pp. 229–294, 2002. View at: Publisher Site  Google Scholar
 J. W. Chamberlain, “Interplanetary gas. II. Expansion of a model solar corona,” Astrophysical Journal, vol. 131, pp. 47–56, 1960. View at: Google Scholar
 J. W. Chamberlain, “Interplanetary gas. III. A hydrodynamic model of the corona,” Astrophysical Journal, vol. 133, pp. 675–687, 1961. View at: Google Scholar
 J. Lemaire and V. Pierrard, “Kinetic models of solar and polar winds,” Astrophysics and Space Science, vol. 277, no. 12, pp. 169–180, 2001. View at: Publisher Site  Google Scholar
 I. Zouganelis, M. Maksimovic, N. MeyerVernet, H. Lamy, and K. Issautier, “A transonic collisionless model of the solar wind,” Astrophysical Journal, vol. 606, no. 1, pp. 542–554, 2004. View at: Publisher Site  Google Scholar
 I. Ballai, J. C. Thelen, and B. Roberts, “Solitary waves in a Hall solar wind plasma,” Astronomy and Astrophysics, vol. 404, no. 2, pp. 701–707, 2003. View at: Google Scholar
 I. Ballai, “Nonlinear waves in solar plasmas,” PADEU, vol. 15, pp. 73–82, 2005. View at: Google Scholar
 I. Bailai, E. ForgácsDajka, and A. Marcu, “Dispersive shock waves in the solar wind,” Astronomische Nachrichten, vol. 328, no. 8, pp. 734–737, 2007. View at: Publisher Site  Google Scholar
 J. Ashmall and J. Richardson, “Comparison of Voyager shocks in solar cycle 23,” in Physics of Collisionless Shocks, G. Li, G. P. Zank, and C. T. Russell, Eds., pp. 299–303, American Institute of Physics, 2005. View at: Google Scholar
 T. V. Zaqarashvili, V. Kukhianidze, and M. L. Khodachenko, “Propagation of a sausage soliton in the solar lower atmosphere observed by Hinode/SOT,” Monthly Notices of the Royal Astronomical Society: Letters, vol. 404, no. 1, pp. L74–L78, 2010. View at: Publisher Site  Google Scholar
 P. K. Shukla and A. A. Mamun, “Solitons, shocks and vortices in dusty plasmas,” New Journal of Physics, vol. 5, pp. 17.1–17.37, 2003. View at: Google Scholar
 M. Khan, S. Ghosh, S. Sarkar, and M. R. Gupta, “Ion acoustic shock waves in a dusty plasma,” Physica Scripta, vol. T116, pp. 53–56, 2005. View at: Publisher Site  Google Scholar
 V. M. Nakariakov and E. Verwichte, “Coronal waves and oscillations,” Living Reviews in Solar Physics, vol. 2, pp. 3–65, 2005. View at: Google Scholar
 M. S. Ruderman, “Nonlinear waves in the solar atmosphere,” Philosophical Transactions of the Royal Society A, vol. 364, no. 1839, pp. 485–504, 2006. View at: Publisher Site  Google Scholar
 P. K. Karmakar, “A numerical investigation of electric current conservation associated with solar wind plasma under GESmodel approach,” Journal of Physics: Conference Series, vol. 208, Article ID 012072, 2010. View at: Publisher Site  Google Scholar
 E. Grun, B. Gustfson, I. Mann et al., “Interstellar dust in the heliosphere,” Astronomy and Astrophysics, vol. 286, pp. 915–924, 1994. View at: Google Scholar
 P. K. Karmakar, “Application of inertiainduced excitation theory for nonlinear acoustic modes in colloidal plasma equilibrium flow,” Pramana  Journal of Physics, vol. 68, no. 4, pp. 631–648, 2007. View at: Publisher Site  Google Scholar
 P. K. Karmakar, “Nonlinear stability of pulsational mode of gravitational collapse in selfgravitating hydrostatically bounded dust molecular cloud,” Pramana  Journal of Physics, vol. 76, no. 6, pp. 945–956, 2011. View at: Publisher Site  Google Scholar
Copyright
Copyright © 2011 P. K. Karmakar. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.