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Main Authors: Reefe, Michael, McDonald, Michael, Chatzikos, Marios, Seebeck, Jerome, Mushotzky, Richard, Veilleux, Sylvain, Allen, Steven, Bayliss, Matthew, Calzadilla, Michael, Canning, Rebecca, Floyd, Benjamin, Gaspari, Massimo, Hlavacek-Larrondo, Julie, McNamara, Brian, Russell, Helen, Sharon, Keren, Somboonpanyakul, Taweewat
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.08619
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author Reefe, Michael
McDonald, Michael
Chatzikos, Marios
Seebeck, Jerome
Mushotzky, Richard
Veilleux, Sylvain
Allen, Steven
Bayliss, Matthew
Calzadilla, Michael
Canning, Rebecca
Floyd, Benjamin
Gaspari, Massimo
Hlavacek-Larrondo, Julie
McNamara, Brian
Russell, Helen
Sharon, Keren
Somboonpanyakul, Taweewat
author_facet Reefe, Michael
McDonald, Michael
Chatzikos, Marios
Seebeck, Jerome
Mushotzky, Richard
Veilleux, Sylvain
Allen, Steven
Bayliss, Matthew
Calzadilla, Michael
Canning, Rebecca
Floyd, Benjamin
Gaspari, Massimo
Hlavacek-Larrondo, Julie
McNamara, Brian
Russell, Helen
Sharon, Keren
Somboonpanyakul, Taweewat
contents In the centers of many galaxy clusters, the hot ($\sim$10$^7$ K) intracluster medium (ICM) can become dense enough that it should cool on short timescales. However, the low measured star formation rates in massive central galaxies and absence of soft X-ray lines from cooling gas suggest that most of this gas never cools - this is known as the "cooling flow problem." The latest observations suggest that black hole jets are maintaining the vast majority of gas at high temperatures. A cooling flow has yet to be fully mapped through all gas phases in any galaxy cluster. Here, we present new observations of the Phoenix cluster using the James Webb Space Telescope to map the [Ne VI] $λ$7.652$μ$m emission line, allowing us to probe gas at 10$^{5.5}$ K on large scales. These data show extended [Ne VI] emission cospatial with (i) the cooling peak in the ICM, (ii) the coolest gas phases, and (iii) sites of active star formation. Taken together, these imply a recent episode of rapid cooling, causing a short-lived spike in the cooling rate which we estimate to be 5,000-23,000 M$_\odot$ yr$^{-1}$. These data provide the first large-scale map of gas at temperatures between 10$^5$-10$^6$ K in a cluster core, and highlight the critical role that black hole feedback plays in not only regulating but also promoting cooling.
format Preprint
id arxiv_https___arxiv_org_abs_2502_08619
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Directly Imaging the Cooling Flow in the Phoenix Cluster
Reefe, Michael
McDonald, Michael
Chatzikos, Marios
Seebeck, Jerome
Mushotzky, Richard
Veilleux, Sylvain
Allen, Steven
Bayliss, Matthew
Calzadilla, Michael
Canning, Rebecca
Floyd, Benjamin
Gaspari, Massimo
Hlavacek-Larrondo, Julie
McNamara, Brian
Russell, Helen
Sharon, Keren
Somboonpanyakul, Taweewat
Astrophysics of Galaxies
In the centers of many galaxy clusters, the hot ($\sim$10$^7$ K) intracluster medium (ICM) can become dense enough that it should cool on short timescales. However, the low measured star formation rates in massive central galaxies and absence of soft X-ray lines from cooling gas suggest that most of this gas never cools - this is known as the "cooling flow problem." The latest observations suggest that black hole jets are maintaining the vast majority of gas at high temperatures. A cooling flow has yet to be fully mapped through all gas phases in any galaxy cluster. Here, we present new observations of the Phoenix cluster using the James Webb Space Telescope to map the [Ne VI] $λ$7.652$μ$m emission line, allowing us to probe gas at 10$^{5.5}$ K on large scales. These data show extended [Ne VI] emission cospatial with (i) the cooling peak in the ICM, (ii) the coolest gas phases, and (iii) sites of active star formation. Taken together, these imply a recent episode of rapid cooling, causing a short-lived spike in the cooling rate which we estimate to be 5,000-23,000 M$_\odot$ yr$^{-1}$. These data provide the first large-scale map of gas at temperatures between 10$^5$-10$^6$ K in a cluster core, and highlight the critical role that black hole feedback plays in not only regulating but also promoting cooling.
title Directly Imaging the Cooling Flow in the Phoenix Cluster
topic Astrophysics of Galaxies
url https://arxiv.org/abs/2502.08619