Scientists confirm presence of standing shocks in black hole accretion flows
Sadie Harley
scientific editor
Robert Egan
associate editor
A team led by Prof. Mao Jirong from the Yunnan Observatories of the Chinese Academy of Sciences, in collaboration with international researchers, has recently published a study in confirming the presence of a standing shock in low-angular-momentum black hole accretion modes.
Using general relativistic magnetohydrodynamic (GRMHD) simulations, the researchers identified the stationary shock phenomenon in accretion flows around black holes.
Accretion occurs around compact objects due to their strong gravitational fields. The physics of accretion is the frontier of high-energy astrophysical research and a key factor in understanding galaxy formation and evolution.
Since the Event Horizon Telescope (EHT) captured the first image of a black hole's (BH) shadow in 2019, studying accretion near a black hole's event horizon has become a top priority in the field.
While it has long been hypothesized that shocks could form in accretion flows near central black holes鈥攚ith "standing shocks" being defined by their fixed positions鈥攕cientific consensus on their existence has remained elusive.
To address this gap, the team conducted both two- and three-dimensional MHD simulations within the framework of general relativity, focusing on black hole accretion dynamics.
They found that in low-angular-momentum accretion modes, a shock forms consistently near the central black hole and maintains a stable position throughout the accretion process鈥攑roviding direct evidence for the existence of standing shocks.
Furthermore, standing shocks appear in "standard and normal evolution" (SANE) accretion disks but are absent in "magnetic arrested disk" (MAD) systems, a distinction that refines models of black hole accretion.
The study also links standing shocks to a well-documented astrophysical phenomenon: quasi-periodic oscillations (QPOs). As standing shocks oscillate at fixed locations, they accelerate charged particles; the radiation emitted by these accelerated particles matches the periodic signals observed in X-ray binaries and active galactic nuclei鈥攐ffering a new explanation for QPO origins.
"This study advances our understanding of accretion physics, a field central to unraveling black hole behavior and galaxy evolution," said Prof. Mao.
More information: Jirong Mao et al, Low-angular-momentum Black Hole Accretion: First General Relativistic Magnetohydrodynamic Evidence of Standing Shocks, The Astrophysical Journal (2025).
Journal information: Astrophysical Journal
Provided by Chinese Academy of Sciences
