An infared image of the cluster. Three narrow slices of the infrared spectrum are represented in this color composite. The colors have been balanced to accentuate the red galaxies at a distance of 10.5 billion light years. For an animated gif of this image, see: http://bit.ly/wp4aFv
Pasadena, CA--A team of astronomers has discovered the most distant cluster of red galaxies ever observed using FourStar, a new and powerful near-infrared camera on the 6.5m Magellan Baade Telescope. The galaxy cluster is located 10.5 billion light years away in the direction of the constellation Leo. It is made up of 30 galaxies packed closely together, forming the earliest known “galaxy city” in the universe. The findings will be published in the Astrophysical Journal Letters.
Remarkably, the cluster was completely missed by previous surveys, which searched this region of the sky for thousands of hours and were conducted by all the major ground- and space-based observing facilities, including the Hubble Space Telescope. Despite these intense observations, accurate distances for such faint and distant galaxies were missing until the advent of FourStar.
Eric Persson of the Carnegie Observatories* led the development of the new camera that enabled these observations. Persson and his team--which includes Carnegie’s David Murphy, Andy Monson, Dan Kelson, Pat McCarthy, and Ryan Quadri--equipped FourStar with five special filters to collect images that are sensitive to narrow slices of the near-infrared spectrum. This powerful approach allows them to measure accurate distances between Earth and thousands of distant galaxies at one time, providing a 3-D map of the early universe.
The 3-D map revealed the conspicuous concentration of galaxies that existed when the universe was only three billion years old.
“This means the galaxy cluster is still young and should continue to grow into an extremely dense structure possibly containing thousands of galaxies,” explained lead author Lee Spitler of Australia’s Swinburne University of Technology.
Studying this system will help astronomers understand how galaxies are influenced by their environment, evolve, and assemble into larger structures.
The finding is part of a larger survey, the FourStar Galaxy Evolution Survey ("Z-FOURGE"), led by Dr. Ivo Labbé, a former Carnegie postdoctoral fellow, now at Leiden Observatory in the Netherlands. The focus of the survey is to address a classical problem in observational astronomy: determining distances. Only then do you know if a point of light is a star in our Milky Way, a small nearby galaxy, or a large one very far away.
The Z-FOURGE observations are being conducted using the Magellan 6.5- meter telescope at Carnegie’s Las Campanas Observatory in Chile. From the first six months of the survey, the team obtained accurate distances for faint galaxies over a region roughly one-fifth the apparent size of the Moon. Though the area is relatively small, they found about a thousand galaxies at even greater distances than the new cluster.
“The excellent image quality and sensitivity of Magellan and FourStar really make the difference,”Labbé said. “We look forward to many more exciting and unexpected discoveries!”
For more information about this project, visit: http://z-fourge.obs.carnegiescience.edu/.
*The full list of the research team is: Karl Glazebrook, Glenn G. Kacprzak, Ivo Labbé (PI), Daniel D. Kelson, Patrick J. McCarthy, Andy Monson, David Murphy, Casey Papovich, S. Eric Persson, Ryan Quadri, Lee R. Spitler, Caroline M. S. Straatman, Vithal Tilvi, Kim-Vy H. Tran, and Pieter van Dokkum.
Funding for this project came from the Carnegie Institution for Science; Swinburne University; Sterrewacht Leiden, Leiden University; Department of Physics and Astronomy, Texas A&M University; Department of Astronomy, Yale University; the Australian Research Council, Discovery Program; the Commonwealth of Australia; University of New South Wales; and the National Collaborative Research Infrastructure Strategy of the Australian Federal Government. The funding sources for FourStar are the Carnegie Institution for Science, the National Science Foundation, the Monell Foundation, Yale University, and Texas A&M University.
Remarkably, the cluster was completely missed by previous surveys, which searched this region of the sky for thousands of hours and were conducted by all the major ground- and space-based observing facilities, including the Hubble Space Telescope. Despite these intense observations, accurate distances for such faint and distant galaxies were missing until the advent of FourStar.
Eric Persson of the Carnegie Observatories* led the development of the new camera that enabled these observations. Persson and his team--which includes Carnegie’s David Murphy, Andy Monson, Dan Kelson, Pat McCarthy, and Ryan Quadri--equipped FourStar with five special filters to collect images that are sensitive to narrow slices of the near-infrared spectrum. This powerful approach allows them to measure accurate distances between Earth and thousands of distant galaxies at one time, providing a 3-D map of the early universe.
The 3-D map revealed the conspicuous concentration of galaxies that existed when the universe was only three billion years old.
“This means the galaxy cluster is still young and should continue to grow into an extremely dense structure possibly containing thousands of galaxies,” explained lead author Lee Spitler of Australia’s Swinburne University of Technology.
Studying this system will help astronomers understand how galaxies are influenced by their environment, evolve, and assemble into larger structures.
The finding is part of a larger survey, the FourStar Galaxy Evolution Survey ("Z-FOURGE"), led by Dr. Ivo Labbé, a former Carnegie postdoctoral fellow, now at Leiden Observatory in the Netherlands. The focus of the survey is to address a classical problem in observational astronomy: determining distances. Only then do you know if a point of light is a star in our Milky Way, a small nearby galaxy, or a large one very far away.
The Z-FOURGE observations are being conducted using the Magellan 6.5- meter telescope at Carnegie’s Las Campanas Observatory in Chile. From the first six months of the survey, the team obtained accurate distances for faint galaxies over a region roughly one-fifth the apparent size of the Moon. Though the area is relatively small, they found about a thousand galaxies at even greater distances than the new cluster.
“The excellent image quality and sensitivity of Magellan and FourStar really make the difference,”Labbé said. “We look forward to many more exciting and unexpected discoveries!”
For more information about this project, visit: http://z-fourge.obs.carnegiescience.edu/.
*****
*The full list of the research team is: Karl Glazebrook, Glenn G. Kacprzak, Ivo Labbé (PI), Daniel D. Kelson, Patrick J. McCarthy, Andy Monson, David Murphy, Casey Papovich, S. Eric Persson, Ryan Quadri, Lee R. Spitler, Caroline M. S. Straatman, Vithal Tilvi, Kim-Vy H. Tran, and Pieter van Dokkum.
Funding for this project came from the Carnegie Institution for Science; Swinburne University; Sterrewacht Leiden, Leiden University; Department of Physics and Astronomy, Texas A&M University; Department of Astronomy, Yale University; the Australian Research Council, Discovery Program; the Commonwealth of Australia; University of New South Wales; and the National Collaborative Research Infrastructure Strategy of the Australian Federal Government. The funding sources for FourStar are the Carnegie Institution for Science, the National Science Foundation, the Monell Foundation, Yale University, and Texas A&M University.
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