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1.
Pulsars are presently believed to be rotating neutron stars with large frozen-in magnetic fields normally assumed to be dipole fields. It has been shown that such a star must possess a magnetosphere if it rotates sufficiently rapidly. By assuming that the magnetic field is dipolar, and unaffected by the trapped particles in the magnetosphere, and that the field dipole axis is parallel to the rotation axis, Goldreich and Julian determined many of the properties of the magnetosphere. In this paper is given a self-consistent model of the closed field lines of a pulsar magnetosphere. Using this model, it is shown that, close to the star, the above assumptions of Goldreich and Julian are justified. Their results are extended to the oblique rotator as well as to stars with magnetic multipoles of arbitrary order and arbitrary orientation.Supported in part by the U.S. Atomic Energy Commission under Grant 2171T. 相似文献
2.
R. Bharuthram P. K. Shukla M. Y. Yu V. N. Pavlenko 《Astrophysics and Space Science》1987,135(2):211-218
A set of coupled nonlinear differential equations which govern the dynamics of finite amplitude electromagnetic waves in the presence of an external current gradient in a magnetized electron-positron plasma has been derived. It is shown that the current gradient can make shear Alfvén-like waves unstable. A quasi-stationary solution of the mode-coupling equations is the well-localized dipole vortex. Application of our results to plasma transport in the pulsar magnetosphere is briefly discussed. 相似文献
3.
O.A. Pokhotelov O.G. Onishchenko V.P. Pavlenko L. Stenflo P.K. Shukla A.V. Bogdanov F.F. Kamenets 《Astrophysics and Space Science》2001,277(3):497-505
A set of equations which governs the nonlinear dynamics of drift–Alfvén waves in an inhomogeneous relativistic electron-positron
plasma with a small admixture of heavy ions is derived. It is shown that these equations admit a stationary solution in the
form of a two-scale dipolar vortex. The conditions for the existence of such structures are discussed. It is shown that the
presence of heavy ions in are lativistic electron-positron plasma significantly reinforces the spatial localization of the
solitary waves which results in the appearance of exponentially localized vortex structures. It is also shown that the small
scale micropulse structure of radio pulsar radiation (e.g., in the case of the pulsar PSR 0905+08) can be interpreted as a
signature of the vortex structure in the outer region of the pulsar polar magnetosphere.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
4.
A. V. Gurevich Ya. N. Istomin 《Monthly notices of the Royal Astronomical Society》2007,377(4):1663-1667
The analysis of observations of pulsar B1931+24 shows that the mechanism of the spin-down of a rotating magnetized neutron star is due to the plasma generation in its magnetosphere and, consequently, the radio emission generation. The unique observation of the switch on and switch off of this pulsar allows us to distinguish between the energy loss in the absence of radio emission (the magnetodipole radiation) and the current loss due to the rotation energy expenditure to the relativistic plasma generation and acceleration in the pulsar magnetosphere. The inclination angle χ, the angle between the rotation axis and the magnetic dipole axis, can be stationary for this pulsar, χ=χst . From observations and theory it follows that χst = 59° . 相似文献
5.
Ya. Istomin 《Astrophysics and Space Science》2001,278(1-2):77-80
We have developed a numerical code for the propagation of different electromagnetic modes in a pulsar magnetosphere filled
by a relativistic, streaming electron-positron plasma in a strong, curved magnetic field. We determine the trajectories, limiting
polarization and damping of the waves leaving the magnetosphere.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
6.
We consider the polarization behaviour of radio waves propagating through an ultrarelativistic highly magnetized electron-positron
plasma in a pulsar magnetosphere. The rotation of magnetosphere gives rise to the wave mode coupling in the polarization-limiting
region. The process is shown to cause considerable circular polarization in the linearly polarized normal waves. Thus, the
circular polarization observed for a number of pulsars, despite the linear polarization of the emitted normal waves, can be
attributed to the limiting-polarization effect.
This revised version was published online in August 2006 with corrections to the Cover Date. 相似文献
7.
Assuming some hydrogen atoms are distributed in the magnetosphere of a pulsar, the gas we are dealing with is a mixture of plasma and hydrogen atoms. Because the induced electrical field in the plasma surrounding the pulsar is very strong, due to the rotation of the pulsar associated with a strong magnetic field, the electric polarization of an atom will include the nonlinear term of the electric field. We obtain the nonlinear dispersion relation for the mixed gas from the Maxwell equations and derive the nonlinear Schrödinger equation, which has solitons as its solution under a certain condition. The curvature radiation of solitons moving along the magnetic field lines is a plausible way to explain the strong radio emission which comes from a pulsar, particularly some field lines existing near the light cylinder with radii of curvature smaller than the radius of the pulsar. 相似文献
8.
Vasily S. Beskin 《Astrophysics and Space Science》2001,277(1-2):237-246
In this review I discuss briefly the main theoretical problems concerning radio pulsars and formulate the observations aimed
at a verification of the current models of pulsar magnetosphere and the radio emission mechanism.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
9.
L. Mestel 《Astrophysics and Space Science》2000,272(1-3):283-294
Domains of the pulsar magnetosphere, both within and without the light-cylinder, are studied under varying provisional assumptions.
Some of the qualitative features emerging should persist in the ultimate synthesis of a completely self-consistent model.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
10.
Irakli S. Nanobashvili 《Astrophysics and Space Science》2004,294(3-4):125-134
Plasma mechanism for the generation of toroidal magnetic field in the magnetosphere of Crab pulsar is presented. The mechanism
is based on the development of parametric type instability in the relativistic electron-positron plasma of the pulsar magnetosphere.
As a result of plasma corotation with pulsar and its magnetic field, the effect of plasma radial braking takes place and the
time dependence of plasma particle radial velocity is harmonic. This triggers the development of parametric type instability
in the relativistic plasma of the pulsar magnetosphere. The energy for this process is drawn from the slowing down of pulsar
rotation. 相似文献
11.
Nonlinear propagation of electrostatic modes in ultrarelativistic dense elelectron-positron gravito-plasma at the polar cap region of pulsar magnetosphere is considered. A nonlinear Schrödinger equation is obtained from the reductive perturbation method which predicts the existence of Langmuir dark solitons. Relevance of the propagating dark solitons to the pulsar radio emission is discussed. 相似文献
12.
G.Z. Machabeli G.Z. Mchedlishvili D.E. Shapakidze 《Astrophysics and Space Science》2000,271(3):277-292
A simple mechanichal problem of the force-free motion of a relativistic bead inside a rotating pipe is examined. A relevant change of shape of the pipe is considered. The
force-free motion of the bead along the rotating pipe is examined as the motion in a differentially rotating medium. The differential
rotation proves to be resembling a well known case of the Couette flow without outer cylinder. The determination of vectoral fields (magnetic field) in the rotating charged mediums (plasma) is
problematic for the laboratory observer. Therefore the same problem is examined in the framework of general relativity, that is the physical quantities are considered in the inertial frame and non-inertial frame with no rotational in homogeneity.
The problematic character of the determination of the physical quantity in the differentially rotating madium relative to
the inertial observer is explained. It is shown that at certain large distances from the rotation center the pipe does not
rotate. However, at rather small distances its shape takes on the appearance of an expanded spiral-like configuration. A possible relevance of the obtained results to the motion of a relativistic plasma flows in pulsar magnetosphere
is pointed out. The areas of Crab pulsar's dipole radiation are estimated.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
13.
Cong Yu National Astronomical Observatories/Yunnan Observatory Chinese Academy of Sciences Kunming 《中国天文和天体物理学报》2007,7(6):743-756
We formulate the general relativistic force-free electrodynamics in a new 3 1 language. In this formulation,when we have properly defined electric and magnetic fields,the covariant Maxwell equations could be cast in the traditional form with new vacuum con-stitutive constraint equations. The fundamental equation governing a stationary,axisymmet-ric force-free black hole magnetosphere is derived using this formulation which recasts the Grad-Shafranov equation in a simpler way. Compared to the classic 3 1 system of Thorne and MacDonald,the new system of 3 1 equations is more suitable for numerical use for it keeps the hyperbolic structure of the electrodynamics and avoids the singularity at the event horizon. This formulation could be readily extended to non-relativistic limit and find applica-tions in flat spacetime. We investigate its application to disk wind,black hole magnetosphere and solar physics in both flat and curved spacetime. 相似文献
14.
The motion of charged particles in a pulsar magnetosphere is examined in the present paper. Using the non-relativistic approximation, the trajectories of the charged particles are investigated qualitativley both in the case of axial and in the case of incline rotator. The obtained results can be used for the construction of the pulsar magnetosphere. 相似文献
15.
Jun Pan Peter Coles István Szapudi 《Monthly notices of the Royal Astronomical Society》2007,382(4):1460-1464
Soon after the discovery of radio pulsars in 1967, the pulsars are identified as strongly magnetic (typically 1012 G) rapidly rotating (∼102 − 0.1 Hz) neutron stars. However, the mechanism of particle acceleration in the pulsar magnetosphere has been a longstanding problem. The central problem is why the rotation power manifests itself in both gamma-ray beams and a highly relativistic wind of electron–positron plasmas, which excites surrounding nebulae observed in X-ray. Here we show with a three-dimensional particle simulation for the global axisymmetric magnetosphere that a steady outflow of electron–positron pairs is formed with associated pair sources, which are the gamma-ray emitting regions within the light cylinder. The magnetic field is assumed to be a dipole, and to be consistent, the pair creation rate is taken to be small, so that the model might be applicable to old pulsars such as Geminga. The pair sources are charge-deficient regions around the null surface, and we identify them as the outer gap. The wind mechanism is the electromagnetic induction which brings about fast azimuthal motion and eventually trans-field drift by radiation drag in the close vicinity of the light cylinder and beyond. The wind causes loss of particles from the system. This maintains charge deficiency in the outer gap and pair creation. The model is thus in a steady state, balancing loss and supply of particles. Our simulation implies how the wind coexists with the gamma-ray emitting regions in the pulsar magnetosphere. 相似文献
16.
Vadim Urpin 《Journal of Astrophysics and Astronomy》2017,38(3):41
The magnetospheres around neutron stars should be very particular because of their strong magnetic field and rapid rotation. A study of the pulsar magnetospheres is of crucial importance since it is the key issue to understand how energy outflow to the exterior is produced. In this paper, we discuss magnetohydrodynamic processes in the pulsar magnetosphere. We consider in detail the properties of magnetohydrodynamic waves that can exist in the magnetosphere and their instabilities. These instabilities lead to formation of magnetic structures and can be responsible for short-term variability of the pulsar emission. 相似文献
17.
Yu. A. Rylov 《Astrophysics and Space Science》1984,107(2):381-401
A self-consistent pulsar magnetospheric model with electron-positron pair production is considered. Unlike conventional models, the primary particles (electrons) are accelerated towards the neutron star and their curvature radiation towards a star generates electron-positron plasma near the neutron star. Inside an outflow channel, the generated plasma flows away from the pulsar magnetosphere. A part of the plasma electrons returns and, being accelerated towards the star, regenerate the plasma by their curvature radiation. It is shown that plasma production near the star causes an appearance of positron and electron equatorial belts. The plasma concentration and the flux of the returning electrons are estimated. The portion of the energy entering into the pulsar magnetosphere and its dependence on pulsar parameters are estimated. 相似文献
18.
S. S. Komissarov 《Monthly notices of the Royal Astronomical Society》2006,367(1):19-31
In this paper we present the results of time-dependent simulations of the dipolar axisymmetric magnetospheres of neutron stars carried out within the frameworks of both relativistic magnetohydrodynamics (MHD) and resistive force-free electrodynamics. The results of force-free simulations reveal the inability of our numerical method to accommodate the equatorial current sheets of pulsar magnetospheres, and raise a question mark about the robustness of this approach. On the other hand, the MHD approach allows us to make significant progress. We start with a non-rotating magnetically dominated dipolar magnetosphere and follow its evolution as the stellar rotation is switched on. We find that the time-dependent solution gradually approaches a steady state that is very close to the stationary solution of the pulsar equation found in 1999 by Contopoulos, Kazanas & Fendt. This result suggests that other stationary solutions that have the Y-point located well inside the light cylinder are unstable. The role of particle inertia and pressure on the structure and dynamics of MHD magnetospheres is studied in detail, as well as the potential implications of dissipative processes in the equatorial current sheet. We argue that pulsars may have differentially rotating magnetospheres which develop noticeable structural oscillations, and that this may help to explain the nature of the subpulse phenomena. 相似文献
19.
Ren-Xin Xu Xiao-Hong Cui Guo-Jun Qiao Department of Astronomy School of Physics Peking University Beijing 《中国天文和天体物理学报》2006,6(2):217-226
The global structure of current flows in pulsar magnetosphere is investigated, with rough calculations of the circuit elements. It is emphasized that the potential of the critical field lines (the field lines that intersect the null surface at the light cylinder radius) should be the same as that of interstellar medium, and that pulsars whose rotation axes and magnetic dipole axes are parallel should be positively charged, in order to close the pulsar's current flows. The statistical relation between the radio luminosity and pulsar's electric charge (or the spindown power) may hint that the millisecond pulsars could be low-mass bare strange stars. 相似文献
20.
A. C. -L. Chian 《Astrophysics and Space Science》1996,242(1-2):249-295
We discuss nonlinear mode-mode coupling phenomena in cosmic plasmas. Four problems are considered: (1) nonlinear three-wave processes in the planetary magnetosphere involving the interaction of auroral Langmuir, Alfvén and whistler waves, (2) nonlinear three-wave processes in the solar wind involving the modulation of Langmuir and electromagnetic waves by ion-acoustic waves, (3) order and chaos in nonlinear four-wave processes in cosmic plasmas, and (4) regular and chaotic dynamics of the relativistic Langmuir turbulence and its application to pulsar and AGN emissions. The observational evidence in support of nonlinear wave-wave interactions in space and astrophysical plasmas is presented. 相似文献