<p>Galaxy clusters, the Universe’s largest halo structures, are filled with an X-ray-emitting gas with a temperature between 10 million and 100 million degrees. Their evolution is shaped by energetic processes such as feedback from supermassive black holes (SMBHs) and mergers with other cosmic structures<sup><CitationRef AdditionalCitationIDS="CR2" CitationID="CR1">1</CitationRef>–<CitationRef CitationID="CR3">3</CitationRef></sup>. The imprints of these processes on gas kinematics remain largely unknown, restricting our understanding of energy conversion within clusters<sup><CitationRef CitationID="CR4">4</CitationRef></sup>. High-resolution spectral mapping with the X-Ray Imaging and Spectroscopy Mission (XRISM) observatory<sup><CitationRef CitationID="CR5">5</CitationRef></sup> offers a way forward<sup><CitationRef CitationID="CR6">6</CitationRef>,<CitationRef CitationID="CR7">7</CitationRef></sup>. Here we present XRISM kinematic measurements of the Perseus cluster, radially covering the extent of its cool core. We find direct evidence for at least two dominant drivers of gas motions operating on distinct physical scales: a small-scale driver in the inner approximately 60 kpc, probably associated with the SMBH feedback; and a large-scale driver in the outer core, powered by mergers. This finding suggests that, during the active phase, SMBH feedback drives gas motions, which, if fully dissipated into heat, could have a substantial role in offsetting radiative cooling losses in the Perseus core. Our study underscores the necessity of kinematic mapping observations of extended sources to robustly characterize the velocity fields and their role in the evolution of massive halos. It further offers a kinematic diagnostic for SMBH feedback models.</p>

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Disentangling multiple gas kinematic drivers in the Perseus galaxy cluster

  • Marc Audard,
  • Hisamitsu Awaki,
  • Ralf Ballhausen,
  • Aya Bamba,
  • Ehud Behar,
  • Rozenn Boissay-Malaquin,
  • Laura Brenneman,
  • Gregory V. Brown,
  • Lia Corrales,
  • Elisa Costantini,
  • Renata Cumbee,
  • María Díaz Trigo,
  • Chris Done,
  • Tadayasu Dotani,
  • Ken Ebisawa,
  • Megan E. Eckart,
  • Dominique Eckert,
  • Satoshi Eguchi,
  • Teruaki Enoto,
  • Yuichiro Ezoe,
  • Adam Foster,
  • Ryuichi Fujimoto,
  • Yutaka Fujita,
  • Yasushi Fukazawa,
  • Kotaro Fukushima,
  • Akihiro Furuzawa,
  • Luigi Gallo,
  • Javier A. García,
  • Liyi Gu,
  • Matteo Guainazzi,
  • Kouichi Hagino,
  • Kenji Hamaguchi,
  • Isamu Hatsukade,
  • Katsuhiro Hayashi,
  • Takayuki Hayashi,
  • Natalie Hell,
  • Edmund Hodges-Kluck,
  • Ann Hornschemeier,
  • Yuto Ichinohe,
  • Daiki Ishi,
  • Manabu Ishida,
  • Kumi Ishikawa,
  • Yoshitaka Ishisaki,
  • Jelle Kaastra,
  • Timothy Kallman,
  • Erin Kara,
  • Satoru Katsuda,
  • Yoshiaki Kanemaru,
  • Richard Kelley,
  • Caroline Kilbourne,
  • Shunji Kitamoto,
  • Shogo Kobayashi,
  • Takayoshi Kohmura,
  • Aya Kubota,
  • Maurice Leutenegger,
  • Michael Loewenstein,
  • Yoshitomo Maeda,
  • Maxim Markevitch,
  • Hironori Matsumoto,
  • Kyoko Matsushita,
  • Dan McCammon,
  • Brian McNamara,
  • François Mernier,
  • Eric D. Miller,
  • Jon M. Miller,
  • Ikuyuki Mitsuishi,
  • Misaki Mizumoto,
  • Tsunefumi Mizuno,
  • Koji Mori,
  • Koji Mukai,
  • Hiroshi Murakami,
  • Richard Mushotzky,
  • Hiroshi Nakajima,
  • Kazuhiro Nakazawa,
  • Jan-Uwe Ness,
  • Kumiko Nobukawa,
  • Masayoshi Nobukawa,
  • Hirofumi Noda,
  • Hirokazu Odaka,
  • Shoji Ogawa,
  • Anna Ogorzalek,
  • Takashi Okajima,
  • Naomi Ota,
  • Stephane Paltani,
  • Robert Petre,
  • Paul Plucinsky,
  • Frederick S. Porter,
  • Katja Pottschmidt,
  • Kosuke Sato,
  • Toshiki Sato,
  • Makoto Sawada,
  • Hiromi Seta,
  • Megumi Shidatsu,
  • Aurora Simionescu,
  • Randall Smith,
  • Hiromasa Suzuki,
  • Andrew Szymkowiak,
  • Hiromitsu Takahashi,
  • Mai Takeo,
  • Toru Tamagawa,
  • Keisuke Tamura,
  • Takaaki Tanaka,
  • Atsushi Tanimoto,
  • Makoto Tashiro,
  • Yukikatsu Terada,
  • Yuichi Terashima,
  • Yohko Tsuboi,
  • Masahiro Tsujimoto,
  • Hiroshi Tsunemi,
  • Takeshi G. Tsuru,
  • Ayşegül Tümer,
  • Hiroyuki Uchida,
  • Nagomi Uchida,
  • Yuusuke Uchida,
  • Hideki Uchiyama,
  • Yoshihiro Ueda,
  • Shinichiro Uno,
  • Jacco Vink,
  • Shin Watanabe,
  • Brian J. Williams,
  • Satoshi Yamada,
  • Shinya Yamada,
  • Hiroya Yamaguchi,
  • Kazutaka Yamaoka,
  • Noriko Yamasaki,
  • Makoto Yamauchi,
  • Shigeo Yamauchi,
  • Tahir Yaqoob,
  • Tomokage Yoneyama,
  • Tessei Yoshida,
  • Mihoko Yukita,
  • Ian Drury,
  • Julie Hlavacek-Larrondo,
  • Julian Meunier,
  • Kostas Migkas,
  • Lior Shefler,
  • Phillip C. Stancil,
  • Nhut Truong,
  • Shutaro Ueda,
  • Benjamin Vigneron,
  • John ZuHone,
  • Congyao Zhang,
  • Annie Heinrich,
  • Irina Zhuravleva,
  • Elena Bellomi

摘要

Galaxy clusters, the Universe’s largest halo structures, are filled with an X-ray-emitting gas with a temperature between 10 million and 100 million degrees. Their evolution is shaped by energetic processes such as feedback from supermassive black holes (SMBHs) and mergers with other cosmic structures13. The imprints of these processes on gas kinematics remain largely unknown, restricting our understanding of energy conversion within clusters4. High-resolution spectral mapping with the X-Ray Imaging and Spectroscopy Mission (XRISM) observatory5 offers a way forward6,7. Here we present XRISM kinematic measurements of the Perseus cluster, radially covering the extent of its cool core. We find direct evidence for at least two dominant drivers of gas motions operating on distinct physical scales: a small-scale driver in the inner approximately 60 kpc, probably associated with the SMBH feedback; and a large-scale driver in the outer core, powered by mergers. This finding suggests that, during the active phase, SMBH feedback drives gas motions, which, if fully dissipated into heat, could have a substantial role in offsetting radiative cooling losses in the Perseus core. Our study underscores the necessity of kinematic mapping observations of extended sources to robustly characterize the velocity fields and their role in the evolution of massive halos. It further offers a kinematic diagnostic for SMBH feedback models.