متریک کر-نیومن (به انگلیسی: Kerr-Newman Metric) جوابی برای معادلات انیشتین-ماکسول در نظریه نسبیت عام است که هندسه فضا-زمان را در ناحیه پیرامون یک جرم چرخنده دارای بار الکتریکی توصیف میکند. در این راه حل ثابت کیهانی برابر با صفر در نظر گرفته میشود. این جواب برای توصیف پدیدههای اخترفیزیکی استفاده نمیشود، زیرا از میان اجسام فضایی مشاهده شده تاکنون هیچ یک بار الکتریکی خالص قابل اندازه گیری ندارند و نیز اکنون تصور میشود که ثابت کیهانی مقداری غیر صفر دارد. در عوض این جواب بیشتر برای مقاصد نظری و ریاضی کاربرد دارد.
This solution has not been especially useful for describing non-black-hole astrophysical phenomena, because observed astronomical objects do not possess an appreciable net electric charge, and the magnetic field of stars arise through other processes. As a model of realistic black holes, it omits any description of infalling baryonic matter, light (null dusts) or dark matter, and thus provides at best an incomplete description of stellar mass black holes and active galactic nuclei. The solution is of theoretical and mathematical interest as it does provide a fairly simple cornerstone for further exploration.
The Kerr–Newman solution is a special case of more general exact solutions of the Einstein–Maxwell equations with non-zero cosmological constant.
In 1965, Ezra "Ted" Newman found the axisymmetric solution of Einstein's field equation for a black hole which is both rotating and electrically charged. This formula for the metric tensor is called the Kerr–Newman metric. It is a generalisation of the Kerr metric for an uncharged spinning point-mass, which had been discovered by Roy Kerr two years earlier.
Four related solutions may be summarized by the following table:
Any Kerr–Newman source has its rotation axis aligned with its magnetic axis. Thus, a Kerr–Newman source is different from commonly observed astronomical bodies, for which there is a substantial angle between the rotation axis and the magnetic moment. Specifically, neither the Sun, nor any of the planets in the Solar system have magnetic fields aligned with the spin axis. Thus, while the Kerr solution describes the gravitational field of the Sun and planets, the magnetic fields arise by a different process.
If the Kerr–Newman potential is considered as a model for a classical electron, it predicts an electron having not just a magnetic dipole moment, but also other multipole moments, such as an electric quadrupole moment. An electron quadrupole moment has not yet been experimentally detected; it appears to be zero.
In the G = 0 limit, the electromagnetic fields are those of a charged rotating disk inside a ring where the fields are infinite. The total field energy for this disk is infinite, and so this G=0 limit does not solve the problem of infinite self-energy.
Like the Kerr metric for an uncharged rotating mass, the Kerr–Newman interior solution exists mathematically but is probably not representative of the actual metric of a physically realistic rotating black hole due to issues with the stability of the Cauchy horizon, due to mass inflation driven by infalling matter. Although it represents a generalization of the Kerr metric, it is not considered as very important for astrophysical purposes, since one does not expect that realistic black holes have an significant electric charge (they are expected to have a miniscule positive charge, but only because the proton has a much larger momentum than the electron, and is thus more likely to overcome electrostatic repulsion and be carried by momentum across the horizon).
The Kerr–Newman metric defines a black hole with an event horizon only when the combined charge and angular momentum are sufficiently small:
A 2007 paper by Russian theorist Alexander Burinskii describes an electron as a gravitationally confined ring singularity without an event horizon. It has some, but not all of the predicted properties of a black hole. As Burinskii described it:
In this work we obtain an exact correspondence between the wave function of the Dirac equation and the spinor (twistorial) structure of the Kerr geometry. It allows us to assume that the Kerr–Newman geometry reflects the specific space-time structure of electron, and electron contains really the Kerr–Newman circular string of Compton size.
Minkowski space if the mass M, the charge Q, and the rotational parameter a are all zero. Alternately, if gravity is intended to be removed, Minkowski space arises if the gravitational constant G is zero, without taking the mass and charge to zero. In this case, the electric and magnetic fields are more complicated than simply the fields of a charged magnetic dipole; the zero-gravity limit is not trivial.
The Kerr–Newman metric describes the geometry of spacetime for a rotating charged black hole with mass M, charge Q and angular momentum J. The formula for this metric depends upon what coordinates or coordinate conditions are selected. Two forms are given below: Boyer-Lindquist coordinates, and Kerr-Schild coordinates. The gravitational metric alone is not sufficient to determine a solution to the Einstein field equations; the electromagnetic stress tensor must be given as well. Both are provided in each section.
Notice that k is a unit vector. Here M is the constant mass of the spinning object, Q is the constant charge of the spinning object, η is the Minkowski metric, and a=J/M is a constant rotational parameter of the spinning object. It is understood that the vector is directed along the positive z-axis, i.e. . The quantity r is not the radius, but rather is implicitly defined like this:
Notice that the quantity r becomes the usual radius R
when the rotational parameter a approaches zero. In this form of solution, units are selected so that the speed of light is unity (c = 1). In order to provide a complete solution of the Einstein–Maxwell equations, the Kerr–Newman solution not only includes a formula for the metric tensor, but also a formula for the electromagnetic potential:
In the Kerr–Schild form of the Kerr–Newman metric, the determinant of the metric tensor is everywhere equal to negative one, even near the source.
Electromagnetic fields in Kerr-Schild form
The electric and magnetic fields can be obtained in the usual way by differentiating the four-potential to obtain the electromagnetic field strength tensor. It will be convenient to switch over to three-dimensional vector notation.
The static electric and magnetic fields are derived from the vector potential and the scalar potential like this:
Using the Kerr–Newman formula for the four-potential in the Kerr–Schild form yields the following concise complex formula for the fields:
The quantity omega () in this last equation is similar to the Coulomb potential, except that the radius vector is shifted by an imaginary amount. This complex potential was discussed as early as the nineteenth century, by the French mathematician Paul Émile Appell.
In order to electrically charge and/or spin a neutral and static body, energy has to be applied to the system. Due to the mass–energy equivalence, this energy also has a mass-equivalent; therefore M is always higher than Mirr. If for example the rotational energy of a black hole is extracted via the Penrose processes, the remaining mass-energy will always stay greater than or equal to Mirr.
Event horizons and ergospheres of a charged and spinning black hole in pseudospherical r,θ,φ and cartesian x,y,z coordinates.
Setting to 0 and solving for gives the inner and outer event horizon, which is located at the Boyer-Lindquist coordinate
Repeating this step with gives the inner and outer ergosphere
Testparticle in orbit around a spinning and charged black hole (a/M=0.9, Q/M=0.4)
Equations of motion
For brevity, we further use dimensionless natural units of , with Coulomb's constant, where reduces to and to , and the equations of motion for a testparticle of charge become
with for the total energy and for the axial angular momentum. is the Carter constant:
where is the poloidial component of the testparticle's angular momentum, and the orbital inclination angle.
Ray traced shadow of a spinning and charged black hole with the parameters a²+Q²=1M². The left side of the black hole is rotating towards the observer.
are also conserved quantities.
is the frame dragging induced angular velocity. The shorthand term is defined by
The relation between the coordinate derivatives and the local 3-velocity is
for the radial,
for the poloidial,
for the axial and
for the total local velocity, where
is the axial radius of gyration (local circumference divided by 2π), and
the gravitational time dilation component. The local radial escape velocity for a neutral particle is therefore
^ abStephani, Hans et al. Exact Solutions of Einstein's Field Equations (Cambridge University Press 2003). See page 485 regarding determinant of metric tensor. See page 325 regarding generalizations.
^Punsly, Brian (10 May 1998). "High-energy gamma-ray emission from galactic Kerr–Newman black holes. I. The central engine". The Astrophysical Journal. 498 (2): 646. Bibcode:1998ApJ...498..640P. doi:10.1086/305561. All Kerr–Newman black holes have their rotation axis and magnetic axis aligned; they cannot pulse.
^ abDebney, G. C.; Kerr, R. P.; Schild, A. (1969). "Solutions of the Einstein and Einstein‐Maxwell Equations". Journal of Mathematical Physics. 10 (10): 1842–1854. doi:10.1063/1.1664769.. Especially see equations (7.10), (7.11) and (7.14).
^Burinskii, A. “Kerr Geometry Beyond the Quantum Theory” in Beyond the Quantum, page 321 (Theo Nieuwenhuizen ed., World Scientific 2007). The formula for the vector potential of Burinskii differs from that of Debney et al. merely by a gradient which does not affect the fields.
^Bhat, Manjiri; Dhurandhar, Sanjeev; Dadhich, Naresh (1985). "Energetics of the Kerr-Newman black hole by the penrose process". Journal of Astrophysics and Astronomy. 6 (2): 85–100. doi:10.1007/BF02715080.