Kepler and Swift Capture Early Moments of Baby Supernovae

Researchers View Early Moments of Baby Supernovae

The graphic depicts a light curve of the newly discovered Type Ia supernova, KSN 2011b, from NASA’s Kepler spacecraft. The light curve shows a star’s brightness (vertical axis) as a function of time (horizontal axis) before, during and after the star exploded. The white diagram on the right represents 40 days of continuous observations by Kepler. In the red zoom box, the agua-colored region is the expected ‘bump’ in the data if a companion star is present during a supernova. The measurements remained constant (yellow line) concluding the cause to be the merger of two closely orbiting stars, most likely two white dwarfs. The finding provides the first direct measurements capable of informing scientists of the cause of the blast. Credit: NASA Ames/W. Stenzel

NASA’s Kepler and Swift spacecraft provides new insight into what triggers a Type Ia supernova, allowing astronomers to better calibrate Type Ia supernovae as standard candles – which may eventually lead to a better understand the mysteries of dark energy.

Astronomers are going gaga over newborn supernova measurements taken by NASA’s Kepler and Swift spacecraft, poring over them in hopes of better understanding what sparks these world-shattering stellar explosions. Scientists are particularly fascinated with Type la supernovae, as they can serve as a lighthouse for measuring the vast distances across space.

“Kepler’s unprecedented pre-event supernova observations and Swift’s agility in responding to supernova events have both produced important discoveries at the same time but at very different wavelengths,” says Paul Hertz, Director of Astrophysics. “Not only do we get insight into what triggers a Type Ia supernova, but these data allow us to better calibrate Type Ia supernovae as standard candles, and that has implications for our ability to eventually understand the mysteries of dark energy.”

Type Ia supernovae explode with similar brightness because the exploding object is always a white dwarf, the Earth-sized remnant of a star like the sun. A white dwarf can go supernova by merging with another white dwarf or by pulling too much matter from a nearby companion star, causing a thermonuclear reaction and blowing itself to smithereens.

NASA Spacecraft Capture Early Moments of Baby Supernovae

This computer simulation shows the debris of a Type Ia supernova (brown) slamming into its companion star (blue) at tens of millions of miles per hour. The interaction produces ultraviolet light that escapes as the supernova shell sweeps over the companion, a signal detected by Swift. Credit: UC Berkeley, Daniel Kasen

In studies appearing in Nature on Thursday, Kepler, and Swift have found supporting evidence for both star-pulverizing scenarios.

Researchers studying the Kepler data have caught three new and distant supernovae, and the dataset includes measurements taken before the violent explosions even happened. Known for its planet-hunting prowess and its unceasing gaze, the Kepler space telescope’s exquisitely precise and frequent observations every 30 minutes have allowed astronomers to turn back the clock and dissect the initial moments of a supernova. The finding provides the first direct measurements capable of informing scientists of the cause of the blast.

“Our Kepler supernova discoveries strongly favor the white dwarf merger scenario, while the Swift study, led by Cao, proves that Type Ia supernovae can also arise from single white dwarfs,” said Robert Olling, research associate at the University of Maryland and lead author of the study. “Just as many roads lead to Rome, nature may have several ways to explode white dwarf stars.”

To capture the earliest moments of Type Ia explosions, the research team monitored 400 galaxies for two years using Kepler. The team discovered three events, designated KSN 2011b, KSN 2011c, and KSN 2012a, with measurements taken before, during, and after the explosions.

These early data provide a view into the physical processes that ignite these stellar bombs hundreds of millions of light-years away. When a star goes supernova, the explosive burst of energy ejects the star’s material at hypersonic velocity, emitting a shock wave in all directions. If a companion star is in the neighborhood, the disruption in the shock wave will be recorded in the data.

Scientists found no evidence of a companion star and concluded the cause to be the collision and merger of two closely orbiting stars, most likely two white dwarfs.

Knowing the distance to a galaxy in the Kepler survey was key to characterizing the Type of supernova uncovered by Olling and his colleagues. To determine the distance, the team turned to the powerful telescopes at the Gemini and the W. M. Keck Observatories atop Mauna Kea in Hawaii. These measurements were key for the researchers to conclude that the supernovae they had discovered were of the Type Ia lighthouse variety.

“The Kepler spacecraft has delivered yet another surprise, playing an unexpected role in supernova science by providing the first well-sampled early time light curves of Type Ia supernovae,” said Steve Howell, Kepler project scientist at NASA’s Ames Research Center in Moffett Field, California. “Now in its new mission as K2, the spacecraft will search for more supernovae among many thousands of galaxies.”


Animation showing a binary star system in which a white dwarf accretes matter from a normal companion star. Matter streaming from the red star accumulates on the white dwarf until the dwarf explodes. With its partner destroyed, the normal star careens into space. This scenario results in what astronomers refer to as a Type Ia supernova.
Credit: NASA’s Goddard Space Flight Center/Walt Feimer

A separate group of astronomers have also found intriguing data on a different supernova. Led by California Institute of Technology (Caltech) graduate student Yi Cao, a team using Swift has detected an unprecedented flash of ultraviolet (UV) light in the first few days of a Type Ia supernova. Based on computer simulations of supernovae exploding in binary star systems, the researchers think the UV pulse was emitted when the supernova’s blast wave slammed into and engulfed a nearby companion star.

“If Swift had looked just a day or two later, we would have missed the prompt UV flash entirely,” said Brad Cenko, a Swift team member at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “Thanks to Swift’s wavelength coverage and rapid scheduling capability, it is currently the only spacecraft that can regularly make these observations.”

According to the analysis, the supernova debris slammed into and swept around its companion star, creating a region of UV emission. The peak temperature exceeded 19,000 degrees Fahrenheit (11,000 degrees Celsius) or about twice the surface temperature of the sun.

The explosion, designated iPTF14atg, was first seen on May 3, 2014, in the galaxy IC 831, located about 300 million light-years away in the constellation Coma Berenices. It was discovered through a wide-field robotic observing system known as the intermediate Palomar Transient Factory (iPTF), a multi-institute collaboration led by the Caltech Optical Observatories in California.

“We saw no evidence of this explosion in images taken the previous night, so we found iPTF14atg when it was only about one day old,” Cao said. “Better yet, we confirmed it was a young Type Ia supernova, something we’ve worked hard designing our system to find.”

The team immediately requested follow-up observations from other facilities, including ultraviolet and X-ray observations from NASA’s Swift satellite. Although no X-rays were found, a fading spike of UV light was caught by Swift’s Ultraviolet/Optical Telescope within a few days of the explosion, with no corresponding spike at visible wavelengths. After the flash faded, both UV and visible wavelengths rose together as the supernova brightened.

The UV pulse from iPTF14atg provides strong evidence for the presence of a companion star, but as white dwarfs crashing into each other can also produce supernovae, as demonstrated by the Kepler results, astronomers are working to determine the percentage of supernovae produced by each one.

The scientists add that a better understanding of the differences among Type Ia explosions will help astronomers improve their knowledge of dark energy, a mysterious force that appears to be accelerating cosmic expansion.

References:

“No signature of ejecta interaction with a stellar companion in three type Ia supernovae” by Rob P. Olling, Richard Mushotzky, Edward J. Shaya, Armin Rest, Peter M. Garnavich, Brad E. Tucker, Daniel Kasen, Steve Margheim and Alexei V. Filippenko, 21 May 2015, Nature.
DOI: 10.1038/nature14455

“A strong ultraviolet pulse from a newborn type Ia supernova” by Yi Cao, S. R. Kulkarni, D. Andrew Howell, Avishay Gal-Yam, Mansi M. Kasliwal, Stefano Valenti, J. Johansson, R. Amanullah, A. Goobar, J. Sollerman, F. Taddia, Assaf Horesh, Ilan Sagiv, S. Bradley Cenko, Peter E. Nugent, Iair Arcavi, Jason Surace, P. R. Woźniak, Daniela I. Moody, Umaa D. Rebbapragada, Brian D. Bue and Neil Gehrels, 21 May 2015, Nature.
DOI: 10.1038/nature14440

Ames manages the Kepler and K2 missions for NASA’s Science Mission Directorate. NASA’s Jet Propulsion Laboratory in Pasadena, California, managed Kepler mission development. Ball Aerospace & Technologies Corp. operates the flight system with support from the Laboratory for Atmospheric and Space Physics at the University of Colorado in Boulder.

Swift blasted into orbit November 20, 2004. Managed by Goddard, the mission is operated in collaboration with Penn State University in University Park, Pennsylvania, the Los Alamos National Laboratory in New Mexico, and Orbital Sciences Corp. in Dulles, Virginia. Other partners include the University of Leicester and Mullard Space Science Laboratory in the United Kingdom, Brera Observatory, and the Italian Space Agency in Italy, with additional collaborators in Germany and Japan.

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