Saved in:
Bibliographic Details
Main Authors: Jin, Shilong, Zhao, Xiaofei, Zhang, Yong, Xiong, Chi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.03561
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914178638282752
author Jin, Shilong
Zhao, Xiaofei
Zhang, Yong
Xiong, Chi
author_facet Jin, Shilong
Zhao, Xiaofei
Zhang, Yong
Xiong, Chi
contents By solving a nonlinear Klein-Gordon equation in Kerr geometry, we uncover new phenomena and key characteristics of quantized vortices in quantum fluids near a Kerr black hole. The formation of these vortices induces rotational or turbulent flows, which profoundly alter the fluid properties and revise those dark matter models describing axion condensates, ultralight boson clouds, and other scalar fields in the vicinity of spinning black holes. As macroscopic, quantum, and topological defects, these vortices can stably orbit the black hole over extended periods, establishing their viability as novel probes for investigating black hole physics. For instance, we calculate the angular velocities of orbiting vortices to quantitatively characterize the frame-dragging effect, a classic prediction of general relativity. Additionally, we observe that relatively large vortices are accreted onto the black hole, wrapping around it while undergoing splitting and reconnecting processes. In quantum fluids with high vortex densities, turbulent flows emerge, accompanied by the formation of a vortex boundary layer near the event horizon. Beyond the ergosphere, we find vortex emissions and energetic outbursts, which may provide crucial insights into analogous astrophysical events recently discovered by the XRISM satellite.
format Preprint
id arxiv_https___arxiv_org_abs_2512_03561
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Feeding a Kerr black hole with quantized vortices
Jin, Shilong
Zhao, Xiaofei
Zhang, Yong
Xiong, Chi
General Relativity and Quantum Cosmology
By solving a nonlinear Klein-Gordon equation in Kerr geometry, we uncover new phenomena and key characteristics of quantized vortices in quantum fluids near a Kerr black hole. The formation of these vortices induces rotational or turbulent flows, which profoundly alter the fluid properties and revise those dark matter models describing axion condensates, ultralight boson clouds, and other scalar fields in the vicinity of spinning black holes. As macroscopic, quantum, and topological defects, these vortices can stably orbit the black hole over extended periods, establishing their viability as novel probes for investigating black hole physics. For instance, we calculate the angular velocities of orbiting vortices to quantitatively characterize the frame-dragging effect, a classic prediction of general relativity. Additionally, we observe that relatively large vortices are accreted onto the black hole, wrapping around it while undergoing splitting and reconnecting processes. In quantum fluids with high vortex densities, turbulent flows emerge, accompanied by the formation of a vortex boundary layer near the event horizon. Beyond the ergosphere, we find vortex emissions and energetic outbursts, which may provide crucial insights into analogous astrophysical events recently discovered by the XRISM satellite.
title Feeding a Kerr black hole with quantized vortices
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2512.03561