“Cosmic mirages” confirm accelerated cosmic expansion

These results independently indicate that the expansion of the universe is accelerating, which suggests that the universe must be filled with a mysterious energy component called dark energy.
By | Published: April 11, 2012 | Last updated on May 18, 2023
Quasar-SDSSJ1226-0006
Image of SDSSJ1226-0006, a new gravitationally lensed quasar discovered in this survey. The quasar image in the original image of the Sloan Digital Sky Survey, which has been used for the actual survey to identify gravitational lensing, looks only slightly extended, but the Hubble Space Telescope image clearly exhibits two distinct quasar images (white) as well as a massive galaxy in between the quasar images (orange) that produces gravitational lensing.
Quasars are luminous objects powered by accretion of gas into supermassive black holes at the centers of distant galaxies. A quasar is typically located far away. Gravitational lensing is a phenomenon in which a distant object is split into two or more images due to the gravity of a massive foreground object. The phenomenon of gravitational lensing, often called a “cosmic mirage”, was first discovered in 1979, and since then more than 100 gravitationally lensed quasars have been reported.

An international team of researchers led by Masamune Oguri and Naohisa Inada from the Nara National College of Technology in Japan conducted a large survey to search for gravitationally lensed quasars in the massive data sets of the Sloan Digital Sky Survey (SDSS). During almost 10 years of careful examinations of 100,000 quasars, the team successfully discovered nearly 50 new gravitationally lensed quasars in total, significantly increasing a sample of cosmic mirages.

The frequency of gravitational lensing, which can be measured by counting the number of gravitationally lensed quasars within a given quasar catalog, allows one to infer the expansion speed of the universe because the accelerated expansion increases the distance to each quasar and, therefore, enhances the chance of gravitational lensing.

The team measured the probability of gravitational lensing among distant quasars to be about 0.05 percent, which was then compared with detailed theoretical calculations to extract information on the expansion history. The result indicates that the expansion of the universe is indeed accelerating, which suggests that the universe must be filled with a mysterious energy component called dark energy.

Cosmic-expansion
Illustration of the gravitational lensing measurement of the cosmic expansion speed. The accelerated expansion increases the distance to the quasar, giving rise to higher chance of having a massive galaxy close to the light path to produce gravitational lensing. Credit: Kavli IPMU
“The accelerated cosmic expansion is one of the central problems in modern cosmology,” Oguri said. “In 2011, the Nobel Prize in physics was awarded to the discovery of the accelerated expansion of the universe using observations of distant supernovae. A caution is that this method using supernovae is built on several assumptions, and therefore independent checks of the result are important in order to draw any robust conclusion. Our new result using gravitational lensing not only provides additional strong evidence for the accelerated cosmic expansion, but also is useful for accurate measurements of the expansion speed, which is essential for investigating the nature of dark energy.”

Careful comparisons with other cosmological observations led to the conclusion that dark energy behaves almost like Einstein’s cosmological constant. “Statistical methods on gravitationally lensed quasars have been known to be sensitive to the expansion history of the universe,” Masashi Chiba from Tohoku University said, “therefore actively studied by Japanese researchers in the 1990s. Observations of gravitational lensing at that time already hinted at the presence of dark energy, but both due to the small sample size and large uncertainty in the theoretical modeling of lensing rates, the result was not widely accepted. This research conducted an enormous survey of gravitationally lensed quasars and adopted much more sophisticated theoretical calculations to build a very convincing case for the accelerated cosmic expansion.”

“Studies of dark energy — cosmological constant — were popular in Japan already in the early 1990s, largely because of pioneering work by Fukugita,” said Yasushi Suto from the University of Tokyo. “This survey of gravitationally lensed quasars was initiated and organized by Oguri and Inada, who were graduate students when the survey started, within the large international SDSS collaboration, and they led the team to success. This result is important in that it confirms the presence of dark energy independently from the observation of supernovae.”

Detailed properties of dark energy are planned to be explored in the SuMIRe project, an international survey project led by Kavli IPMU using the Subaru Telescope. “This result demonstrates that Japanese theoretical and observational cosmologists will play an essential role in the SuMIRe project,” Suto said.

“This result creates big momentum for the survey of the cosmic dark energy by the SuMIRe project,” Chiba said.