Secrets of an Earlier Universe Revealed by Red-Supergiant Supernova

Detailed telescope images help scientists learn more about the Universe two billion years after the Big Bang.

An international research team has measured the size of a star dating back 2 billion years after the Big Bang, or more than 11 billion years ago. Detailed images show the exploding star cooling and could help scientists learn more about the stars and galaxies that existed in the early Universe.

Led by researchers at the University of Minnesota Twin Cities, the study was published recently in Nature, the world’s leading peer-reviewed, multidisciplinary science journal.

“This is the first detailed look at a supernova at a much earlier epoch of the Universe’s evolution,” said Patrick Kelly, a lead author of the paper and an associate professor in the University of Minnesota School of Physics and Astronomy. “It’s very exciting because we can learn in detail about an individual star when the Universe was less than a fifth of its current age, and begin to understand if the stars that existed many billions of years ago are different from the ones nearby.”

The red supergiant in question was about 500 times larger than the sun, and it’s located at redshift three, which is about 60 times farther away than any other supernova observed in this detail.

An international research team led by the University of Minnesota Twin Cities has measured the size of a star dating back more than 11 billion years ago using images that show the evolution of the star exploding and cooling. The above image shows the light from the supernova behind the galaxy cluster Abell 370. Credit: Wenlei Chen, NASA

Using data from the Hubble Space Telescope with follow-up spectroscopy using the University of Minnesota’s access to the Large Binocular Telescope, the researchers were able to identify multiple detailed images of the red supergiant because of a phenomenon called gravitational lensing, where mass, such as that in a galaxy, bends light. This magnifies the light emitted from the star.

“The gravitational lens acts as a natural magnifying glass and multiplies Hubble’s power by a factor of eight,” Kelly said. “Here, we see three images. Even though they can be seen at the same time, they show the supernova as it was at different ages separated by several days. We see the supernova rapidly cooling, which allows us to basically reconstruct what happened and study how the supernova cooled in its first few days with just one set of images. It enables us to see a rerun of a supernova.”

The researchers combined this discovery with another one of Kelly’s supernova discoveries from 2014 to estimate how many stars were exploding when the Universe was a small fraction of its current age. They found that there were likely many more supernovae than previously thought.

Panels A-D (clockwise from upper left) show several different stages of the supernova: the location of the host galaxy after the supernova faded, the three images of the host galaxy and the supernova at different phases in its evolution, the three different faces of the evolving supernova, and the different colors of the cooling supernova. Credit: Wenlei Chen, NASA

“Core-collapse supernovae mark the deaths of massive, short-lived stars. The number of core-collapse supernovae we detect can be used to understand how many massive stars were formed in galaxies when the Universe was much younger,” said Wenlei Chen, first author of the paper and a postdoctoral researcher in the University of Minnesota School of Physics and Astronomy.

Reference: “Shock cooling of a red-supergiant supernova at redshift 3 in lensed images” by Wenlei Chen, Patrick L. Kelly, Masamune Oguri, Thomas J. Broadhurst, Jose M. Diego, Najmeh Emami, Alexei V. Filippenko, Tommaso L. Treu and Adi Zitrin, 9 November 2022, Nature.
DOI: 10.1038/s41586-022-05252-5

The research was funded by the National Science Foundation; the Hubble Space Telescope Cycle 27 Archival Research and Frontier Fields program; the World Premier International Research Center Initiative, MEXT, Japan; the United States-Israel Binational Science Foundation; the Ministry of Science & Technology, Israel; the Christopher R. Redlich Fund; and the University of California, Berkeley Miller Institute for Basic Research in Science.

In addition to Kelly and Chen, the research team included University of Minnesota School of Physics and Astronomy researcher Najmeh Emami; University of Tokyo researcher Masamune Oguri; University of the Basque Country research professor Thomas Broadhurst; Instituto de Física de Cantabria researcher Jose Diego; University of California, Berkeley professor Alexei Filippenko; University of California, Los Angeles professor Tommaso Treu; and Ben-Gurion University of the Negev associate professor Adi Zitrin.

An artist’s rendition of a red supergiant star transitioning into a Type II supernova, emitting a violent eruption of radiation and gas on its dying breath before collapsing and exploding. Credit: W. M. Keck Observatory/Adam Makarenko

Detailed telescope images help scientists learn more about the Universe two billion years after the Big Bang.

An international research team has measured the size of a star dating back 2 billion years after the Big Bang, or more than 11 billion years ago. Detailed images show the exploding star cooling and could help scientists learn more about the stars and galaxies that existed in the early Universe.

Led by researchers at the University of Minnesota Twin Cities, the study was published recently in Nature, the world’s leading peer-reviewed, multidisciplinary science journal.

“This is the first detailed look at a supernova at a much earlier epoch of the Universe’s evolution,” said Patrick Kelly, a lead author of the paper and an associate professor in the University of Minnesota School of Physics and Astronomy. “It’s very exciting because we can learn in detail about an individual star when the Universe was less than a fifth of its current age, and begin to understand if the stars that existed many billions of years ago are different from the ones nearby.”

The red supergiant in question was about 500 times larger than the sun, and it’s located at redshift three, which is about 60 times farther away than any other supernova observed in this detail.

An international research team led by the University of Minnesota Twin Cities has measured the size of a star dating back more than 11 billion years ago using images that show the evolution of the star exploding and cooling. The above image shows the light from the supernova behind the galaxy cluster Abell 370. Credit: Wenlei Chen, NASA

Using data from the Hubble Space Telescope with follow-up spectroscopy using the University of Minnesota’s access to the Large Binocular Telescope, the researchers were able to identify multiple detailed images of the red supergiant because of a phenomenon called gravitational lensing, where mass, such as that in a galaxy, bends light. This magnifies the light emitted from the star.

“The gravitational lens acts as a natural magnifying glass and multiplies Hubble’s power by a factor of eight,” Kelly said. “Here, we see three images. Even though they can be seen at the same time, they show the supernova as it was at different ages separated by several days. We see the supernova rapidly cooling, which allows us to basically reconstruct what happened and study how the supernova cooled in its first few days with just one set of images. It enables us to see a rerun of a supernova.”

The researchers combined this discovery with another one of Kelly’s supernova discoveries from 2014 to estimate how many stars were exploding when the Universe was a small fraction of its current age. They found that there were likely many more supernovae than previously thought.

Panels A-D (clockwise from upper left) show several different stages of the supernova: the location of the host galaxy after the supernova faded, the three images of the host galaxy and the supernova at different phases in its evolution, the three different faces of the evolving supernova, and the different colors of the cooling supernova. Credit: Wenlei Chen, NASA

“Core-collapse supernovae mark the deaths of massive, short-lived stars. The number of core-collapse supernovae we detect can be used to understand how many massive stars were formed in galaxies when the Universe was much younger,” said Wenlei Chen, first author of the paper and a postdoctoral researcher in the University of Minnesota School of Physics and Astronomy.

Reference: “Shock cooling of a red-supergiant supernova at redshift 3 in lensed images” by Wenlei Chen, Patrick L. Kelly, Masamune Oguri, Thomas J. Broadhurst, Jose M. Diego, Najmeh Emami, Alexei V. Filippenko, Tommaso L. Treu and Adi Zitrin, 9 November 2022, Nature.
DOI: 10.1038/s41586-022-05252-5

The research was funded by the National Science Foundation; the Hubble Space Telescope Cycle 27 Archival Research and Frontier Fields program; the World Premier International Research Center Initiative, MEXT, Japan; the United States-Israel Binational Science Foundation; the Ministry of Science & Technology, Israel; the Christopher R. Redlich Fund; and the University of California, Berkeley Miller Institute for Basic Research in Science.

In addition to Kelly and Chen, the research team included University of Minnesota School of Physics and Astronomy researcher Najmeh Emami; University of Tokyo researcher Masamune Oguri; University of the Basque Country research professor Thomas Broadhurst; Instituto de Física de Cantabria researcher Jose Diego; University of California, Berkeley professor Alexei Filippenko; University of California, Los Angeles professor Tommaso Treu; and Ben-Gurion University of the Negev associate professor Adi Zitrin.