Constraining simulated black hole feedback in the Perseus Cluster

Authors

  • Andrew Mark Heinrich University of Chicago https://orcid.org/0000-0002-7726-4202
  • Yi-Hao Chen
  • Sebastian Heinz University of Wisconsin-Madison
  • Irina Zhuravleva University of Chicago
  • Eugene Churazov Max Planck Institute for Astrophysics

DOI:

https://doi.org/10.17307/wsc.v1i1.342

Keywords:

Galaxy Clusters, AGN, Black Holes, Simulations

Abstract

Active galactic nuclei in galaxy clusters can produce tightly collimated jets that inject energy into the surrounding intracluster medium (ICM). This feedback process can offset cooling losses from X-ray radiation that otherwise would result in cooling flow structures. Jet-inflated bubbles can heat the cluster via a turbulent cascade. The density fluctuation spectrum inferred from X-ray maps of the cluster shows different levels and scales of turbulence in different regions of the clusters, and can be used to determine the contribution of different driving mechanisms. By applying observational power spectrum techniques to synthetic X-ray data from feedback simulations of the Perseus cluster, we find that the density fluctuation spectra produced by a single episode of jet activity are broadly consistent with analysis of Chandra observations inside 60 kpc. The velocity dispersion effected by the AGN approaches Hitomi's measurement of turbulence in Perseus during the AGN episode, but is underpredicted later in the simulation. A fully established volume-filling turbulent cascade therefore requres multiple periods of jet activity, along with turbulence driven by other processes outside of the inner 60 kpc core. This also suggests the X-ray fluctuations directly associated with the jet bubble substantially contribute to the overall density fluctuation spectrum.

Author Biography

Andrew Mark Heinrich, University of Chicago

Ph.D. Student at the Department of Astronomy & Astrophysics, University of Chicago.

References

Andrew M Heinrich, Yi-Hao Chen, Sebastian Heinz, Irina Zhuravleva, and Eugene Churazov. Constraining blackhole feedback in galaxy clusters from X-ray power spectra. Monthly Notices of the Royal Astronomical Society,505(3):4646–4654, 05 2021.

A. C. Fabian and P. E. J. Nulsen. Subsonic accretion of cooling gas in clusters of galaxies. Monthly Notices ofthe Royal Astronomical Society, 180(3):479–484, 10 1977.

I. Chiu, J. Mohr, M. McDonald, S. Bocquet, M. L. N. Ashby, M. Bayliss, B. A. Benson, L. E. Bleem, M. Brodwin, S. Desai, J. P. Dietrich, W. R. Forman, C. Gangkofner, A. H. Gonzalez, C. Hennig, J. Liu, C. L. Reichardt, A. Saro, B. Stalder, S. A. Stanford, J. Song, T. Schrabback, R.ˇSuhada, V. Strazzullo, and A. Zenteno. Baryon content of massive galaxy clusters at 0.57≤z≤1.33.Monthly Notices of the Royal Astronomical Society,455(1):258–275, 10 2015.

A. C. Fabian. Cooling Flows in Clusters of Galaxies. , 32:277–318, January 1994.

J. R. Peterson, S. M. Kahn, F. B. S. Paerels, J. S. Kaastra, T. Tamura, J. A. M. Bleeker, C. Ferrigno, and J. G. Jernigan. High Resolution X-ray Spectroscopic Constraints on Cooling-Flow Models for Clusters of Galaxies. ,590(1):207–224, oct 2002.

J. S. Sanders, A. C. Fabian, H. R. Russell, S. A. Walker, and K. M. Blundell. Detecting edges in the X-ray surface brightness of galaxy clusters. , 460(2):1898–1911, August 2016.

K. Ehlert, R. Weinberger, C. Pfrommer, R. Pakmor, and V. Springel. Simulations of the dynamics of magnetized jets and cosmic rays in galaxy clusters. , 481(3):2878–2900, December 2018.

H. Y. Karen Yang and Christopher S. Reynolds. How AGN Jets Heat the Intracluster Medium—Insights from Hydrodynamic Simulations. , 829(2):90, October 2016.

Patrick M. Motl, Jack O. Burns, Chris Loken, Michael L. Norman, and Greg Bryan. Formation of Cool Cores in Galaxy Clusters via Hierarchical Mergers. , 606(2):635–653, May 2004.

E. Churazov, W. Forman, C. Jones, and H. Bohringer. Asymmetric, arc minute scale structures around NGC1275. , 356:788–794, April 2000.

S. A. Walker, J. S. Sanders, and A. C. Fabian. What fraction of the density fluctuations in the Perseus cluster core is due to gas sloshing rather than AGN feedback? , 481(2):1718–1725, December 2018.

Hitomi Collaboration. The quiescent intracluster medium in the core of the Perseus cluster.Nature,535(7610):117–121, jul 2016.

I. Zhuravleva, E. Churazov, P. Arevalo, A. A. Schekochihin, S. W. Allen, A. C. Fabian, W. R. Forman, J. S. Sanders, A. Simionescu, R. Sunyaev, A. Vikhlinin, and N. Werner. Gas density fluctuations in the Perseus Cluster: clumping factor and velocity power spectrum. , 450(4):4184–4197, July 2015.

I. Zhuravleva, E. Churazov, A. A. Schekochihin, S. W. Allen, P. Ar ́evalo, A. C. Fabian, W. R. Forman, J. S.Sanders, A. Simionescu, R. Sunyaev, A. Vikhlinin, and N. Werner. Turbulent heating in galaxy clusters brightest in X-rays. Nature, 515(7525):85–87, nov 2014.

J. A. ZuHone, K. Kowalik, E. ̈Ohman, E. Lau, and D. Nagai. The Galaxy Cluster Merger Catalog: An Online Repository of Mock Observations from Simulated Galaxy Cluster Mergers. , 234(1):4, January 2018.

P. Ar ́evalo, E. Churazov, I. Zhuravleva, C. Hernandez-Monteagudo, and M. Revnivtsev. A Mexican hat with holes: calculating low-resolution power spectra from data with gaps. , 426(3):1793–1807, November 2012.

A. Dubey, L. B. Reid, K. Weide, K. Antypas, M. K. Ganapathy, K. Riley, D. Sheeler, and A. Siegal. Extensible Component Based Architecture for FLASH, A Massively Parallel, Multiphysics Simulation Code. Parallel Computing, 35(10-11):512–522, mar 2009.

Yi Hao Chen, Sebastian Heinz, and Torsten A Enßlin. Jets, bubbles, and heat pumps in galaxy clusters. ,489(2):1939–1949, oct 2019.

P. A. G. Scheuer. Morphology and power of radio sources. Extragalactic radio sources; IAU Symposium,97:163–165, 1982.

Matthew J Turk, Britton D Smith, Jeffrey S Oishi, Stephen Skory, Samuel W Skillman, Tom Abel, and Michael L Norman. yt: A MULTI-CODE ANALYSIS TOOLKIT FOR ASTROPHYSICAL SIMULATION DATA. ,192(16pp):9, 2010.

Randall K. Smith, Nancy S. Brickhouse, Duane A. Liedahl, and John C. Raymond. Collisional Plasma Models with APEC/APED: Emission-Line Diagnostics of Hydrogen-like and Helium-like Ions. , 556(2):L91–L95, aug2001.

J. Stutzki, F. Bensch, A. Heithausen, V. Ossenkopf, and M. Zielinsky. On the fractal structure of molecular clouds. , 336:697–720, August 1998.

Daniel Foreman-Mackey, David W. Hogg, Dustin Lang, and Jonathan Goodman. emcee: The MCMC Hammer., 125(925):306–312, feb 2012.

Downloads

Published

2022-02-25

How to Cite

Heinrich, A. M., Chen, Y.-H., Heinz, S., Zhuravleva, I., & Churazov, E. (2022). Constraining simulated black hole feedback in the Perseus Cluster. Proceedings of the Wisconsin Space Conference, 1(1). https://doi.org/10.17307/wsc.v1i1.342

Issue

2021: Advancing Aerospace with Artificial Intelligence

Section

Astronomy and Cosmology

License

Creative Commons License
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.