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Astronomers have discovered one of the most powerful eruptions from a\u00a0black hole\u00a0ever recorded in the system known as SDSS J1531+3414 (SDSS J1531 for short). As explained in\u00a0our press release, this mega-explosion billions of years ago may help explain the formation of a striking pattern of\u00a0star clusters\u00a0around two massive\u00a0galaxies, resembling \u201cbeads on a string.\u201d<\/p>\n
SDSS J1531 is a massive\u00a0galaxy cluster\u00a0containing hundreds of individual galaxies and huge reservoirs of hot gas and\u00a0dark matter. At the center of SDSS J1531, which is located about 3.8 billion\u00a0light-years\u00a0away, two of the cluster\u2019s largest galaxies are colliding with each other.<\/p>\n
Astronomers used several telescopes to study SDSS J1531 including\u00a0NASA\u2019s Chandra X-ray Observatory, and the Low Frequency Array (LOFAR), a\u00a0radio\u00a0telescope. This composite image shows SDSS J1531 in\u00a0X-rays\u00a0from Chandra (blue and purple) that have been combined with radio data from LOFAR (dark pink) as well as an\u00a0optical\u00a0image from the Hubble Space Telescope (appearing as yellow and white). The inset gives a close-in view of the center of SDSS J1531 in optical light, showing the two large galaxies and a set of 19 large clusters of stars, called\u00a0superclusters, stretching across the middle. The image shows these star clusters are arranged in an \u2018S\u2019 formation that resembles beads on a string.<\/p>\n
The multiwavelength data provides signs of an ancient, titanic eruption in SDSS J1531, which a team of researchers think was responsible for creation of the 19 star clusters. Their argument is that an extremely powerful jet from the\u00a0supermassive black holes\u00a0in the center of one of the large galaxies pushed the surrounding hot gas away from the black hole, creating a gigantic cavity. The evidence for a cavity comes from \u201cwings\u201d of bright X-ray emission, seen with Chandra, tracing dense gas near the center of SDSS J1531. These wings are the edge of the cavity and the less dense gas in between is part of the cavity. LOFAR shows radio waves from the remains of the jet\u2019s energetic particles filling in the giant cavity. These features are highlighted in a labeled version of the image.<\/p>\n
The astronomers also discovered cold and warm gas located near the opening of the cavity, detected with the Atacama Large Millimeter and submillimeter Array (ALMA) and the Gemini North Telescope, respectively. A separate graphic shows the optical image with the cold gas added in green (left), and the warm gas added in red (right). The team argues that some of the hot gas pushed away from the black hole eventually cooled to form the cold and warm gas shown. The team thinks tidal effects from the two merging galaxies compressed the gas along curved paths, leading to the star clusters forming in the \u201cbeads on a string\u201d pattern.<\/p>\n
A paper led by Osase Omoruyi of the Center for Astrophysics | Harvard & Smithsonian (CfA) describing these results has recently been published in The Astrophysical Journal and is\u00a0available online here. The authors of the paper are Grant Tremblay (CfA), Francoise Combes (Paris Observatory, France), Timothy Davis (Cardiff University, UK), Michael Gladders (University of Chicago), Alexey Vikhlinin (CfA), Paul Nulsen (CfA), Preeti Kharb (National Centre for Radio Astrophysics \u2014 Tata Institute of Fundamental Research, India ), Stefi Baum (University of Manitoba, Canada), Christopher O\u2019Dea (University of Manitoba, Canada), Keren Sharon (University of Michigan), Bryan Terrazas (Columbia University), Rebecca Nevin (Fermi National Accelerator Laboratory), Aimee Schechter (University of Colorado Boulder), John ZuHone (CfA), Michael McDonald (Massachusetts Institute of Technology), Hakon Dahle (University of Oslo, Norway), Matthew B. Bayliss (University of Cincinnati), Thomas Connor (CfA), Michael Florian (University of Arizona), Jane Rigby (NASA Goddard Space Flight Center), and Sravani Vaddi (Arecibo Observatory)<\/p>\n
NASA\u2019s Marshall Space Flight Center manages the Chandra program. The Smithsonian Astrophysical Observatory\u2019s Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.<\/p>\n \n