澳门开奖结果2023开奖记录 astronomers targeting one of the brightest quasars glowing in the universe some 11 billion years ago say 鈥渟ideline quasars鈥 likely teamed up with it to heat abundant helium gas billions of years ago, preventing small galaxy formation.
CU-Boulder Professor Michael Shull and Research Associate David Syphers used the Hubble Space Telescope to look at the quasar -- the brilliant core of an active galaxy that acted as a 鈥渓ighthouse鈥 for the observations -- to better understand the conditions of the early universe. The scientists studied gaseous material between the telescope and the quasar with a $70 million ultraviolet spectrograph on Hubble designed by a team from CU-Boulder鈥檚 Center for Astrophysics and Space Astronomy.
During a time known as the 鈥渉elium reionization era鈥 some 11 billion years ago, blasts of ionizing radiation from black holes believed to be seated in the cores of quasars stripped electrons from primeval helium atoms, said Shull. The initial ionization that charged up the helium gas in the universe is thought to have occurred sometime shortly after the Big Bang.
鈥淲e think 鈥榮ideline quasars鈥 located out of the telescope鈥檚 view reionized intergalactic helium gas from different directions, preventing it from gravitationally collapsing and forming new generations of stars,鈥 he said. Shull likened the early universe to a hunk of Swiss cheese, where quasars cleared out zones of neutral helium gas in the intergalactic medium that were then 鈥減ierced鈥 by UV observations from the space telescope.
The results of the new study also indicate the helium reionization era of the universe appears to have occurred later than thought, said Shull, a professor in CU-Boulder鈥檚 astrophysical and planetary sciences department. 鈥淲e initially thought the helium reionization era took place about 12 billion years ago,鈥 said Shull. 鈥淏ut now we think it more likely occurred in the 11 to 10 billion-year range, which was a surprise.鈥
A paper on the subject by Shull and Syphers was published online this week in the Astrophysical Journal.
The Cosmic Origins Spectrograph used for the quasar observations aboard Hubble was designed to probe the evolution of galaxies, stars and intergalactic matter.听 The COS team is led by CU Professor James Green of CASA and was installed on Hubble by astronauts during its final servicing mission in 2009. 听COS was built in an industrial partnership between CU and Ball Aerospace & Technologies Corp. of Boulder.
鈥淲hile there are likely hundreds of millions of quasars in the universe, there are only a handful you can use for a study like this,鈥 said Shull. Quasars are nuclei in the center of active galaxies that have 鈥済one haywire鈥 because of supermassive black holes that gorged themselves in the cores, he said. 鈥淔or our purposes, they are just a really bright background light that allows us to see to the edge of the universe, like a headlight shining through fog.鈥
The universe is thought to have begun with the Big Bang that triggered a fireball of searing plasma that expanded and then become cool neutral gas at about 380,000 years, bringing on the 鈥渄ark ages鈥 when there was no light from stars or galaxies, said Shull.听 The dark ages were followed by a period of hydrogen reionization, then the formation of the first galaxies beginning about 13.5 billion years ago.听 The first galaxies era was followed by the rise of quasars some 2 billion years later, which led to the helium reionization era, he said.
The radiation from the huge quasars heated the gas to 20,000 to 40,000 degrees Fahrenheit in intergalactic realms of the early universe, said Shull.听 鈥淚t is important to understand that if the helium gas is heated during the epoch of galaxy formation, it makes it harder for proto-galaxies to hang on to the bulk of their gas.听 In a sense, it鈥檚 like intergalactic global warming.鈥
The team is using COS to probe the 鈥渇ossil record鈥 of gases in the universe, including a structure known as the 鈥渃osmic web鈥 believed to be made of long, narrow filaments of galaxies and intergalactic gas separated by enormous voids. Scientists theorize that a single cosmic web filament may stretch for hundreds of millions of light years, an eye-popping number considering that a single light-year is about 5.9 trillion miles.
COS breaks light into its individual components -- similar to the way raindrops break sunlight into the colors of the rainbow -- and reveals information about the temperature, density, velocity, distance and chemical composition of galaxies, stars and gas clouds.
For the study, Shull and Syphers used 4.5 hours of data from Hubble observations of the quasar, which has a catalog name of HS1700+6416. While some astronomers define quasars as feeding black holes, 鈥淲e don鈥檛 know if these objects feed once, or feed several times,鈥 Shull said.听 They are thought to survive only a few million years or perhaps a few hundred million years, a brief blink in time compared to the age of the universe, he said.
鈥淥ur own Milky Way has a dormant black hole in its center,鈥 said Shull. 鈥淲ho knows? Maybe our Milky Way used to be a quasar.鈥
The first quasar, short for 鈥渜uasi-stellar radio source,鈥 was discovered 50 years ago this month by Caltech astronomer Maarten Schmidt. The quasar he observed, 3C-273, is located roughly 2 billion years from Earth and is 40 times more luminous than an entire galaxy of 100 billion stars. That quasar is receding from Earth at 15 percent of the speed of light, with related winds blowing millions of miles per hour, said Shull.
Contact:
Michael Shull, 303-492-7827
Michael.Shull@colorado.edu
Jim Scott, CU-Boulder media relations, 303-492-3114
Jim.Scott@colorado.edu
A new CU-Boulder study shows that distant quasars teamed up to stifle the formation of small galaxies billions of years ago. Image courtesy NASA
