2026-06-15 ミシガン大学
The accretion disk of NGC 4151 is shown blue, immediately surrounding the galaxy’s central black hole. Scientists, including University of Michigan astronomers, are showing how winds or outflows from the accretion disk reshape its host galaxy. The winds are shown as wispy light blue lines blowing across the more orange clouds surrounding the black hole. Image credit: JAXA (Used under a CC BY 4.0 INT license)
<関連情報>
- https://news.umich.edu/revealing-how-and-when-a-black-holes-mighty-winds-can-squash-star-formation/
- https://iopscience.iop.org/article/10.3847/2041-8213/adee9b
NGC 4151における降着駆動型風フィードバックのXRISM分光観測 XRISM Spectroscopy of Accretion-driven Wind Feedback in NGC 4151
Xin Xiang, Jon M. Miller, Ehud Behar, Rozenn Boissay-Malaquin, Laura Brenneman, Margaret Buhariwalla, Doyee Byun, Chris Done, Luigi Gallo, Dimitra Gerolymatou
The Astrophysical Journal Letters Published: 2025 July 25
DOI:10.3847/2041-8213/adee9b
Abstract
The hottest, most ionized, and fastest winds driven by accretion onto massive black holes have the potential to reshape their host galaxies. Calorimeter-resolution X-ray spectroscopy is the ideal tool to understand this feedback mode, as it enables accurate estimates of the physical characteristics needed to determine the wind’s kinetic power. We report on a photoionization analysis of five observations of the Seyfert 1.5 galaxy NGC 4151, obtained with XRISM/Resolve in 2023 and 2024. In the Fe K band, individual spectra require as many as six wind absorption components. Slow “warm absorbers” (WAs; vout ∼ 100–1000 km s−1), “very fast outflows” (VFOs; vout ∼ 103–104 km s−1), and “ultrafast outflows” (UFOs; vout ∼ 104–105 km s−1 or 0.033–0.33c) are detected simultaneously and indicate a stratified, multiphase wind. Fast and variable emission components suggest that the wind is axially asymmetric. All of the wind components have mass flow rates comparable to or in excess of the mass accretion rate, though the slowest zones may be “failed” winds that do not escape. Two UFO components have kinetic luminosities that exceed the theoretical threshold of Lkin ≥ 0.5% LEdd necessary to strip the host bulge of gas and halt star formation, even after corrections for plausible filling factors. The bulk properties of the observed winds are consistent with magnetocentrifugal driving, where the density depends on the radius as n ∝ r−1.5, but radiative driving and other mechanisms may also be important. Numerous complexities and variability require further analysis.
