Magnetic Reconnection and Hot Spot Formation in Black Hole Accretion Disks

Ripperda, Bart; Bacchini, Fabio; Philippov, Alexander

doi:10.3847/1538-4357/ababab

Cited by 181 publications

(168 citation statements)

References 86 publications

Supporting

Mentioning

152

Contrasting

Order By: Relevance

“…The highest-energy particles resulting from reconnection are further energized by shear-driven acceleration, i.e., reconnection can mediate particle injection into shear acceleration. Our work lends support to spinesheath models of jet emission and can explain the origin of radioemitting electrons at the boundaries of relativistic jets (see Ripperda et al 2020 for an alternative explanation).…”

Section: Discussionsupporting

confidence: 75%

Reconnection-driven Particle Acceleration in Relativistic Shear Flows

Sironi

Rowan

Narayan

2021

ApJL

View full text Add to dashboard Cite

Particle energization in shear flows is invoked to explain nonthermal emission from the boundaries of relativistic astrophysical jets. Yet the physics of particle injection, i.e., the mechanism that allows thermal particles to participate in shear-driven acceleration, remains unknown. With particle-in-cell simulations, we study the development of Kelvin-Helmholtz (KH) instabilities seeded by the velocity shear between a relativistic magnetically dominated electron-positron jet and a weakly magnetized electron-ion ambient plasma. We show that, in their nonlinear stages, KH vortices generate kinetic-scale reconnection layers, which efficiently energize the jet particles, thus providing a first-principles mechanism for particle injection into shear-driven acceleration. Our work lends support to spine-sheath models of jet emission-with a fast core/spine surrounded by a slower sheath -and can explain the origin of radio-emitting electrons at the boundaries of relativistic jets.

show abstract

Section: Discussionsupporting

confidence: 75%

Reconnection-driven Particle Acceleration in Relativistic Shear Flows

Sironi

Rowan

Narayan

2021

ApJL

View full text Add to dashboard Cite

show abstract

“…An important assumption made in our model is that we include only thermal electron populations. For sources such as Sgr A*, emission from electrons with a non-thermal energy-distribution function is thought to be important to explain the observed time variability and the high frequency emission (Ball et al 2016;Mao et al 2017;Gravity Collaboration et al 2018;Davelaar et al 2018;Ripperda et al 2020;Dexter et al 2020;Porth et al 2020;Petersen and Gammie 2020). However, at 230 GHz, time-averaged images of this model will look similar to the thermal case when adding nonthermal electrons (Davelaar et al 2018), although it is shown in that work that high-spin models of M87 do become more optically thin because of this addition.…”

Section: Radiative Modelsmentioning

confidence: 99%

“…In SANE simulations, on the other hand, no magnetic 'pile-up' occurs, causing a radical change in the observed source morphology. Whether an accretion flow is MAD or SANE depends on the initial conditions of the magnetic field and the size of the accretion disc (see, e.g., Ripperda et al (2020). The radiative models considered in this work consist of a single-electron-temperature, disc-dominated model (Mościbrodzka et al 2009), and a two-electron-temperature, jet-dominated model (Mościbrodzka et al 2014;Davelaar et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Visibility of black hole shadows in low-luminosity AGN

Bronzwaer

Davelaar

Younsi

et al. 2020

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

Accreting black holes tend to display a characteristic dark central region called the black-hole shadow, which depends only on spacetime/observer geometry and which conveys information about the black hole’s mass and spin. Conversely, the observed central brightness depression, or image shadow, additionally depends on the morphology of the emission region. In this paper, we investigate the astrophysical requirements for observing a meaningful black-hole shadow in GRMHD-based models of accreting black holes. In particular, we identify two processes by which the image shadow can differ from the black-hole shadow: evacuation of the innermost region of the accretion flow, which can render the image shadow larger than the black-hole shadow, and obscuration of the black-hole shadow by optically thick regions of the accretion flow, which can render the image shadow smaller than the black-hole shadow, or eliminate it altogether. We investigate in which models the image shadows of our models match their corresponding black-hole shadows, and in which models the two deviate from each other. We find that, given a compact and optically thin emission region, our models allow for measurement of the black-hole shadow size to an accuracy of 5%. We show that these conditions are generally met for all MAD simulations we considered, as well as some of the SANE simulations.

show abstract

“…The longest variability timescales in the observed TeV emission, for example, in M87, have recently been linked to recurring periods of efficient Blandford/Znajek (Blandford & Znajek 1977) type outflows induced by the accretion of magnetic flux tubes (Parfrey et al 2015;Mahlmann et al 2020). Reconnection and plasmoid formation in BH accretion processes are likely to act on much shorter timescales (studied in the ideal limit by, e.g., Nathanail et al 2020) and involve relevant physical nonideal electric fields (analyzed in the resistive limit by, e.g., Ripperda et al 2020). A large array of work makes use of numerical laboratories set up in (GR)FFE in order to simulate the most extreme environments of the universe while constantly breaking their own limits.…”

Section: Introductionmentioning

confidence: 99%

Computational general relativistic force-free electrodynamics

Mahlmann

Aloy

Mewes

et al. 2021

A&A

View full text Add to dashboard Cite

Scientific codes are an indispensable link between theory and experiment; in (astro-)plasma physics, such numerical tools are one window into the universe’s most extreme flows of energy. The discretization of Maxwell’s equations – needed to make highly magnetized (astro)physical plasma amenable to its numerical modeling – introduces numerical diffusion. It acts as a source of dissipation independent of the system’s physical constituents. Understanding the numerical diffusion of scientific codes is the key to classifying their reliability. It gives specific limits in which the results of numerical experiments are physical. We aim at quantifying and characterizing the numerical diffusion properties of our recently developed numerical tool for the simulation of general relativistic force-free electrodynamics by calibrating and comparing it with other strategies found in the literature. Our code correctly models smooth waves of highly magnetized plasma. We evaluate the limits of general relativistic force-free electrodynamics in the context of current sheets and tearing mode instabilities. We identify that the current parallel to the magnetic field (j∥), in combination with the breakdown of general relativistic force-free electrodynamics across current sheets, impairs the physical modeling of resistive instabilities. We find that at least eight numerical cells per characteristic size of interest (e.g., the wavelength in plasma waves or the transverse width of a current sheet) are needed to find consistency between resistivity of numerical and of physical origins. High-order discretization of the force-free current allows us to provide almost ideal orders of convergence for (smooth) plasma wave dynamics. The physical modeling of resistive layers requires suitable current prescriptions or a sub-grid modeling for the evolution of j∥.

show abstract

Magnetic Reconnection and Hot Spot Formation in Black Hole Accretion Disks

Cited by 181 publications

References 86 publications

Reconnection-driven Particle Acceleration in Relativistic Shear Flows

Reconnection-driven Particle Acceleration in Relativistic Shear Flows

Visibility of black hole shadows in low-luminosity AGN

Computational general relativistic force-free electrodynamics

Contact Info

Product

Resources

About