252 research outputs found
Ab-initio pulsar magnetosphere: the role of general relativity
It has recently been demonstrated that self-consistent particle-in-cell
simulations of low-obliquity pulsar magnetospheres in flat spacetime show weak
particle acceleration and no pair production near the poles. We investigate the
validity of this conclusion in a more realistic spacetime geometry via
general-relativistic particle-in-cell simulations of the aligned pulsar
magnetospheres with pair formation. We find that the addition of frame-dragging
effect makes local current density along the magnetic field larger than the
Goldreich-Julian value, which leads to unscreened parallel electric fields and
the ignition of a pair cascade. When pair production is active, we observe
field oscillations in the open field bundle which could be related to pulsar
radio emission. We conclude that general relativistic effects are essential for
the existence of pulsar mechanism in low obliquity rotators.Comment: 5 pages, 4 figure, submitted to ApJLetter
Extracting black-hole rotational energy: The generalized Penrose process
In the case involving particles the necessary and sufficient condition for
the Penrose process to extract energy from a rotating black hole is absorption
of particles with negative energies and angular momenta. No torque at the
black-hole horizon occurs. In this article we consider the case of arbitrary
fields or matter described by an unspecified, general energy-momentum tensor
and show that the necessary and sufficient condition for
extraction of a black hole's rotational energy is analogous to that in the
mechanical Penrose process: absorption of negative energy and negative angular
momentum. We also show that a necessary condition for the Penrose process to
occur is for the Noether current (the conserved energy-momentum density vector)
to be spacelike or past directed (timelike or null) on some part of the
horizon. In the particle case, our general criterion for the occurrence of a
Penrose process reproduces the standard result. In the case of relativistic
jet-producing "magnetically arrested disks" we show that the negative energy
and angular-momentum absorption condition is obeyed when the Blandford-Znajek
mechanism is at work, and hence the high energy extraction efficiency up to
found in recent numerical simulations of such accretion flows
results from tapping the black hole's rotational energy through the Penrose
process. We show how black-hole rotational energy extraction works in this case
by describing the Penrose process in terms of the Noether current.Comment: 24 pages, 14 figures, version published in Phys. Rev.
A Phase Lag between Disk and Corona in GRMHD Simulations of Precessing Tilted Accretion Disks
In the course of its evolution, a black hole (BH) accretes gas from a wide
range of directions. Given a random accretion event, the typical angular
momentum of an accretion disc would be tilted by 60 relative to
the BH spin. Misalignment causes the disc to precess at a rate that increases
with BH spin and tilt angle. We present the first general-relativistic
magnetohydrodynamic (GRMHD) simulations spanning a full precession period of
highly tilted (60), moderately thin () accretion discs around
a rapidly spinning () BH. While the disc and jets precess in phase,
we find that the corona, sandwiched between the two, lags behind by . For spectral models of BH accretion, the implication is that hard
non-thermal (corona) emission lags behind the softer (disc) emission, thus
potentially explaining some properties of the hard energy lags seen in Type-C
low frequency quasi-periodic oscillations in X-Ray binaries. While strong jets
are unaffected by this disc-corona lag, weak jets stall when encountering the
lagging corona at distances black hole radii. This interaction may
quench large-scale jet formation.Comment: 5 pages, 4 figures, submitted to MNRAS, see YouTube playlist for 3D
renderings:
https://www.youtube.com/playlist?list=PLDO1oeU33GwmwOV_Hp9s7572JdU8JPSS
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