J 2018

Radiation Reaction of Charged Particles Orbiting a Magnetized Schwarzschild Black Hole

TURSUNOV, Arman, Martin KOLOŠ, Zdeněk STUCHLÍK a Dmitri V. GAL'TSOV

Základní údaje

Originální název

Radiation Reaction of Charged Particles Orbiting a Magnetized Schwarzschild Black Hole

Autoři

TURSUNOV, Arman (860 Uzbekistán, garant, domácí), Martin KOLOŠ (203 Česká republika, domácí), Zdeněk STUCHLÍK (203 Česká republika, domácí) a Dmitri V. GAL'TSOV (643 Rusko)

Vydání

Astrophysical Journal, 2018, 0004-637X

Další údaje

Jazyk

angličtina

Typ výsledku

Článek v odborném periodiku

Obor

10308 Astronomy

Stát vydavatele

Velká Británie a Severní Irsko

Utajení

není předmětem státního či obchodního tajemství

Odkazy

URL

Kód RIV

RIV/47813059:19240/18:A0000257

Organizace

Filozoficko-přírodovědecká fakulta – Slezská univerzita v Opavě – Repozitář

DOI

http://dx.doi.org/10.3847/1538-4357/aac7c5

UT WoS

000436539700002

Klíčová slova anglicky

accretion; accretion disks; black hole physics; magnetic fields; radiation mechanisms: non-thermal; relativistic processes

Štítky

CTP, GB14-37086G, GJ16-03564Y, SGS-14-2016, ÚF

Příznaky

Mezinárodní význam, Recenzováno

Návaznosti

GB14-37086G, projekt VaV. GJ16-03564Y, projekt VaV.
Změněno: 4. 4. 2019 09:30, Jan Hladík

Anotace

V originále

In many astrophysically relevant situations, radiation-reaction forces acting upon a charge cannot be ignored, and the question of the location and stability of circular orbits in such a regime arises. The motion of a point charge with radiation reaction in flat spacetime is described by the Lorenz-Dirac (LD) equation, while in curved spacetime it is described by the DeWitt-Brehme (DWB) equation containing the Ricci term and a tail term. We show that for the motion of elementary particles in vacuum metrics, the DWB equation can be reduced to the covariant form of the LD equation, which we use here. Generically, the LD equation is plagued by runaway solutions, so we discuss computational ways of avoiding this problem when constructing numerical solutions. We also use the first iteration of the covariant LD equation, which is the covariant Landau-Lifshitz equation, comparing the results of these two approaches and showing the smallness of the third-order Schott term in the ultrarelativistic case. We calculate the corresponding energy and angular momentum loss of a particle and study the damping of charged particle oscillations around an equilibrium radius. We find that, depending on the orientation of the Lorentz force, the oscillating charged particle either spirals down to the black hole or stabilizes the circular orbit by decaying its oscillations. The latter case leads to the interesting new result of the particle orbit shifting outwards from the black hole. We also discuss the astrophysical relevance of the presented approach and provide estimates of the main parameters of the model.
Zobrazeno: 15. 11. 2024 06:20