Birth of bright galaxies lit up early universe

The 75-foot-tall South Pole Telescope is located at the Amundsen Scott South Pole station in Antarctica. (Credit: Daniel Luong-Van) UC BERKELEY / U. CHICAGO (US) — The birth of the first massive galaxies was an explosive event in the early…

The 75-foot-tall South Pole Telescope is located at the Amundsen Scott South Pole station in Antarctica. (Credit: Daniel Luong-Van) UC BERKELEY / U. CHICAGO (US) — The birth of the first massive galaxies was an explosive event in the early universe, according to new data.

Findings indicate this period of galaxy formation happened faster and ended sooner than suspected.
These extremely bright, active galaxies lit up the universe by the time it was 750 million years old, or about 13 billion years ago, reports Oliver Zahn, a postdoctoral fellow at the Berkeley Center for Cosmological Physics (BCCP) at the University of California, Berkeley, who led the analysis of data from the South Pole Telescope.

The South Pole Telescope recorded temperature fluctuations in the cosmic microwave background, the light left over from the Big Bang, to study the period of cosmological evolution when the first stars and galaxies formed early in the history of the universe. The image, only a third of which was used for the current analysis, shows variations in millionths of a degree Kelvin. (Credit: South Pole Telescope Collaboration)

Straight from the SourceRead the original studyDOI: 10.1088/0004-637X/756/1/65
The data provide new constraints on the universe’s first era of galaxy formation, called the Epoch of Reionization. Most astronomers think that early stars came to life in massive gas clouds, generating the first galaxies.
The energetic light pumped out by these stars is thought to have ionized the hydrogen gas in and around the galaxies, creating “ionization bubbles” millions of light years across that left a lasting, telltale signature in the cosmic background radiation (CMB).
This relic light from the early universe is visible today everywhere in the sky and was first mapped by UC Berkeley physicist and Nobel laureate George Smoot, founder of the BCCP.
“We find that the Epoch of Reionization lasted less than 500 million years and began when the universe was at least 250 million years old,” Zahn says. “Before this measurement, scientists believed that reionization lasted 750 million years or longer, and had no evidence as to when reionization began.”
The first epoch of ionization occurred after the universe was born in the Big Bang. Everything was so hot that all the gas, mostly hydrogen, was ionized. The universe only cooled enough for electrons to latch onto protons to form neutral hydrogen atoms when the universe was about 400,000 years old.
“Studying the Epoch of Reionization is important because it represents one of the few ways by which we can study the first stars and galaxies,” says study co-author John Carlstrom of the University of Chicago.
The epoch’s short duration also suggests that monster galaxies with more than a billion stars played a key role in the reionization, since smaller galaxies would have formed much earlier.
Zahn and UC Berkeley post-doctoral fellow Christian Reichardt, along with colleagues at the University of Chicago, which operates the telescope, report their findings in the Astrophysical Journal.
Wealth of new data
The latest results are based on a new analysis that combines measurements taken by the South Pole Telescope at three frequencies and extends these measurements to a larger area covering approximately 2 percent of the sky. The 10-meter South Pole Telescope operates at millimeter wavelengths to make high-resolution images of the cosmic microwave background and its polarization.
When the new data were combined with earlier data from the WMAP (Wilkinson Microwave Anisotropy Probe) satellite, Zahn, Reichardt, and colleagues were able to put stringent constraints on when the epoch of reionization began, and how long it lasted.
“Our data mostly tells you the duration of the Epoch of Reionization, while WMAP mostly tells you when, on average, it happened, so both together tell you the evolution of ionization over time,” Zahn explains.
Astronomers were unsure whether they would be able to constrain the Epoch of Reionization using the cosmic background radiation, says Zahn, because of uncertainty over how stars formed, clustered, and spewed ionizing radiation into the interstellar medium in the early universe.
But over the past decade, various groups, including one at Harvard University that Zahn belonged to as a graduate student, developed models of these processes, and Zahn has used them to work backward to put limits on when the era began and ended.
“In their study of the epoch of reionization, people have been focused on the spectra of distant quasars and galaxies,” adds Zahn. “Now the CMB is adding a wealth of information to this field.”
This is only the beginning of what astronomers expect to learn about reionization from the South Pole Telescope, says Reichardt. The current results are based on only the first third of the full telescope survey.
Additionally, work is under way to combine the telescope’s maps with ones made with the Herschel satellite to further increase the sensitivity to the reionization signal.
“We expect to measure the duration of reionization to less than 50 million years with the current survey,” Reichardt notes. “With planned upgrades to the instrument, we hope to improve this even further in the next five years.”
The 75-foot-tall South Pole Telescope at the Amundsen-Scott South Pole station in Antarctica was specifically designed to detect signals of reionization in the Cosmic Microwave Background, and allow astronomers to measure the extent of the partially ionized phase. The signal came from cosmic background radiation interacting with electrons in the ionization bubbles, which created small hot and cold spots in the CMB based on whether a bubble was moving toward or away from us.
The South Pole Telescope collaboration is led by the University of Chicago and includes research groups at Argonne National Laboratory, Cardiff University, Case Western Reserve University, Harvard University, Ludwig-Maximilians-Universitat, Smithsonian Astrophysical Observatory, McGill University, UC Berkeley, UC Davis, University of Colorado at Boulder and University of Michigan, as well as individual scientists at several other institutions.
The South Pole Telescope is funded primarily by the National Science Foundation’s Office of Polar Programs. Partial support is also provided by the NSF-funded Physics Frontier Center of the Kavli Institute for Cosmological Physics at the University of Chicago, the Kavli Foundation, and the Gordon and Betty Moore Foundation.
Sources: UC Berkeley and University of Chicago