UCLA Astronomers Use Split Images Of Quasars To Measure Expansion Of The Universe

MessageToEagle.com – UCLA astronomers use split images of quasars to produce a new estimate of the Hubble constant.

These images can be used to measure the rate in which the universe is expanding: quasars, researchers say.

The question of how quickly the universe is expanding has been bugging astronomers for almost a century. Different studies keep coming up with different answers — which has some researchers wondering if they’ve overlooked a key mechanism in the machinery that drives the cosmos.

A Hubble Space Telescope picture of a doubly imaged quasar. Credit: NASA Hubble Space Telescope, Tommaso Treu/UCLA, and Birrer et al
A Hubble Space Telescope picture of a doubly imaged quasar. Credit: NASA Hubble Space Telescope, Tommaso Treu/UCLA, and Birrer et al

At the heart of the dispute is the Hubble constant, a number that relates distances to the redshifts of galaxies — the amount that light is stretched as it travels to Earth through the expanding universe. Estimates for the Hubble constant range from about 67 to 73 kilometers per second per megaparsec, meaning that two points in space 1 megaparsec apart (the equivalent of 3.26 million light-years) are racing away from each other at a speed between 67 and 73 kilometers per second.

“The Hubble constant anchors the physical scale of the universe,” Simon Birrer, a UCLA postdoctoral scholar and lead author of the study, said in a press release.

Without a precise value for the Hubble constant, astronomers can’t accurately determine the sizes of remote galaxies, the age of the universe or the expansion history of the cosmos.

Most methods for deriving the Hubble constant have two ingredients:

  • a distance to some source of light and
  • that light source’s redshift.

The scientists chose one specific subset of quasars — those whose light has been bent by the gravity of an intervening galaxy, which produces two side-by-side images of the quasar on the sky.

Light from the two images takes different routes to Earth. When the quasar’s brightness fluctuates, the two images flicker one after another, rather than at the same time. The delay in time between those two flickers, along with information about the meddling galaxy’s gravitational field, can be used to trace the light’s journey and deduce the distances from Earth to both the quasar and the foreground galaxy. Knowing the redshifts of the quasar and galaxy enabled the scientists to estimate how quickly the universe is expanding.

The UCLA team, as part of the international H0liCOW collaboration, had previously applied the technique to study quadruply imaged quasars, in which four images of a quasar appear around a foreground galaxy. But quadruple images are not nearly as common — double-image quasars are thought to be about five times as abundant as the quadruple ones.

To demonstrate the technique, the UCLA-led team studied a doubly imaged quasar known as SDSS J1206+4332; they relied on data from the Hubble Space Telescope, the Gemini and W.M. Keck observatories, and from the Cosmological Monitoring of Gravitational Lenses, or COSMOGRAIL, network — a program managed by Switzerland’s Ecole Polytechnique Federale de Lausanne that is aimed at determining the Hubble constant.

Images of the quasar were taken for several years to precisely measure the time delay between the images. Then, to get the best estimate possible of the Hubble constant, they combined the data gathered on that quasar with data that had previously been gathered by their H0liCOW collaboration on three quadruply imaged quasars.

“The beauty of this measurement is that it’s highly complementary to and independent of others,” Treu said.

The team came up with the Hubble Constant estimate of about 72.5 kilometers per second per megaparsec. The researchers are still looking for more quasars to improve the precision of the technique.

Paper

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