Distant Flares and Nearby Remnants

An X-ray image of the Tycho supernova remnant built up from years of observations by the Chandra space telescope, showing the clumpy shape of the explosion's debris. New NuSTAR data will locate energetic sites of cosmic ray acceleration within the remnant. Image credit: NASA/CXC/RIKEN & GSFC/T. Sato et al; DSS.   Download Image

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NuSTAR recently observed the distant gamma-ray blazar 4FGL J1428.9+5406 in response to a flare detected by NASA’s Fermi-LAT gamma-ray telescope. Blazars are a subclass of active galaxies—that is, galaxies containing a central supermassive black hole that is actively consuming matter—capable of launching relativistic jets aligned with our line of sight. These objects are highly variable and can produce bright flares lasting from a few days to several weeks. In the early Universe, blazars are typically faint gamma-ray sources and are only detectable during such flare events. These rare flares offer valuable insights into the physics of black hole jets at redshifts greater than 3—that is, within the first 2 billion years after the Big Bang. This NuSTAR observation of 4FGL J1428.9+5406 was triggered by a team monitoring about 80 high-redshift blazars with Fermi-LAT. Their program aims to collect near-simultaneous data across multiple wavelengths, from radio to X-ray, which are essential for probing the origin of the flare and constraining the power of the jet. Understanding how such powerful jets are launched and sustained in the early Universe will inform models of black hole growth and feedback during this epoch of high activity.

Last week, NuSTAR observed the Tycho supernova remnant, the remains of a stellar explosion that was famously visible to the naked eye 453 years ago. Young supernova remnants like Tycho are known to accelerate cosmic rays, such as electrons, to ultra-relativistic energies exceeding 1 TeV. This extreme phenomenon can be detected in the high energy X-ray band through synchrotron radiation emitted by these energetic electrons. NuSTAR first observed the Tycho remnant in 2014 for a total of 750 ks—more than eight days of exposure time—showcasing its exceptional high energy X-ray imaging and spectral capabilities by pinpointing the most energetic acceleration sites down to arcminute scales within this 9-arcminute-wide remnant, and precisely measuring their synchrotron spectra to high X-ray energies of 40 keV. A new observation begun last week totaling 500 ks, or nearly six days, will reveal how Tycho's electron acceleration has evolved over the past decade, providing a unique opportunity to tightly constrain the spectrum of accelerated electrons, deepen our understanding of cosmic-ray acceleration mechanisms, and estimate Tycho's contribution to the most energetic Galactic cosmic rays. For a related study by the same team of researchers on a similar source, see this recent article about Cassiopeia A.

Authors: Andrea Gokus (McDonnell Center Postdoctoral Fellow, Washington University), Jooyun Woo (Postdoctoral scholar, Columbia University), Hannah Earnshaw (NuSTAR Project Scientist, Caltech).

Source: NASA's Nuclear Spectroscopic Telescope Array (NuSTAR)/News

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The Clumpy and Lumpy Death of a Star

Tycho supernova remnant

Credit: X-ray: NASA/CXC/RIKEN & GSFC/T. Sato et al; Optical: DSS

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A Tour of Tycho's Supernova Remnant - More Animations

Astronomers now know that Tycho's new star was not new at all. Rather it signaled the death of a star in a supernova, an explosion so bright that it can outshine the light from an entire galaxy. This particular supernova was a Type Ia, which occurs when a white dwarf star pulls material from, or merges with, a nearby companion star until a violent explosion is triggered. The white dwarf star is obliterated, sending its debris hurtling into space.

As with many supernova remnants, the Tycho supernova remnant, as it's known today (or "Tycho," for short), glows brightly in X-ray light because shock waves — similar to sonic booms from supersonic aircraft — generated by the stellar explosion heat the stellar debris up to millions of degrees. In its two decades of operation, NASA's Chandra X-ray Observatory has captured unparalleled X-ray images of many supernova remnants. 

Chandra reveals an intriguing pattern of bright clumps and fainter areas in Tycho. What caused this thicket of knots in the aftermath of this explosion? Did the explosion itself cause this clumpiness, or was it something that happened afterward? 

This latest image of Tycho from Chandra is providing clues. To emphasize the clumps in the image and the three-dimensional nature of Tycho, scientists selected two narrow ranges of X-ray energies to isolate material (silicon, colored red) moving away from Earth, and moving towards us (also silicon, colored blue). The other colors in the image (yellow, green, blue-green, orange and purple) show a broad range of different energies and elements, and a mixture of directions of motion. In this new composite image, Chandra's X-ray data have been combined with an optical image of the stars in the same field of view from the Digitized Sky Survey.

By comparing the Chandra image of Tycho to two different computer simulations, researchers were able to test their ideas against actual data. One of the simulations began with clumpy debris from the explosion. The other started with smooth debris from the explosion and then the clumpiness appeared afterwards as the supernova remnant evolved and tiny irregularities were magnified.

A statistical analysis using a technique that is sensitive to the number and size of clumps and holes in images was then used. Comparing results for the Chandra and simulated images, scientists found that the Tycho supernova remnant strongly resembles a scenario in which the clumps came from the explosion itself. While scientists are not sure how, one possibility is that star's explosion had multiple ignition points, like dynamite sticks being set off simultaneously in different locations. 

Understanding the details of how these stars explode is important because it may improve the reliability of the use of Type Ia supernovas "standard candles" — that is, objects with known inherent brightness, which scientists can use to determine their distance. This is very important for studying the expansion of the universe. These supernovae also sprinkle elements such as iron and silicon, that are essential for life as we know it, into the next generation of stars and planets. 

A paper describing these results appeared in the July 10th, 2019 issue of The Astrophysical Journal and is available online. The authors are Toshiki Sato (RIKEN in Saitama, Japan, and NASA's Goddard Space Flight Center in Greenbelt, Maryland), John (Jack) Hughes (Rutgers University in Piscataway, New Jersey), Brian Williams, (NASA's Goddard Space Flight Center), and Mikio Morii (The Institute of Statistical Mathematics in Tokyo, Japan).

3D printed model of Tycho's Supernova Remnant

Credit: RIKEN/G. Ferrand, et al & NASA/CXC/SAO/A. Jubett, N. Wolk & K. Arcand

Another team of astronomers, led by Gilles Ferrand of RIKEN in Saitama, Japan, has constructed their own three-dimensional computer models of a Type Ia supernova remnant as it changes with time. Their work shows that initial asymmetries in the simulated supernova explosion are required so that the model of the ensuing supernova remnant closely resembles the Chandra image of Tycho, at a similar age. This conclusion is similar to that made by Sato and his team. 

A paper describing the results by Ferrand and co-authors appeared in the June 1st, 2019 issue of The Astrophysical Journal and is available online. 

NASA's Marshall Space Flight Center manages the  Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science and flight operations from Cambridge, Massachusetts.

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Fast Facts for Tycho's Supernova Remnant:

Scale: Image is about 12 arcmin (45 light years) across.
Category: Supernovas & Supernova Remnants
Coordinates (J2000):  RA 00h 25m 17s | Dec +64° 08' 37"
Constellation:  Cassiopeia
Observation Date: 14 pointings between Oct 1, 2001 & April 22, 2016
Observation Time: 336 hours 2 minutes (14 days 0 hours 2 minutes)
Obs. ID: 115, 3837, 7539, 8551, 10093-10097; 10902-10904; 10906, 15998
Instrument: ACIS
Also Known As:  G120.1+01.4, SN 1572
References: Sato, T. et al. 2019, ApJ, 879, 64; arXiv:1903.00764
Color Code: X-ray Broadband: Red: 0.3-1.2 keV, Yellow: 1.2-1.6 keV, Cyan: 1.6-2.26 keV, Navy: 2.2-4.1 keV, Purple: 4.4-6.1 keV; X-ray Motion Shift Orange: 1.7666-1.7812 keV, Blue: 1.9564-1.971 keV; Optical: Red, Blue
Distance Estimate:  About 13,000 light years

Source: NASA’s Chandra X-ray Observatory

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Tycho's Supernova Remnant: Chandra Movie Captures Expanding Debris From a Stellar Explosion

Tycho's supernova remnant
Credit X-ray: NASA/CXC/GSFC/B.Williams et al; Optical: DSS 

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A Tour of G1.9+0.3

When the star that created this supernova remnant exploded in 1572, it was so bright that it was visible during the day. And though he wasn't the first or only person to observe this stellar spectacle, the Danish astronomer Tycho Brahe wrote a book about his extensive observations of the event, gaining the honor of it being named after him.

In modern times, astronomers have observed the debris field from this explosion - what is now known as Tycho's supernova remnant - using data from NASA's Chandra X-ray Observatory, the NSF's Karl G.

Jansky Very Large Array (VLA) and many other telescopes. Today, they know that the Tycho remnant was created by the explosion of a white dwarf star, making it part of the so-called Type Ia class of supernovas used to track the expansion of the Universe.

Since much of the material being flung out from the shattered star has been heated by shock waves - similar to sonic booms from supersonic planes - passing through it, the remnant glows strongly in X-ray light. Astronomers have now used Chandra observations from 2000 through 2015 to create the longest movie of the Tycho remnant's X-ray evolution over time, using five different images. This shows the expansion from the explosion is still continuing about 450 years later, as seen from Earth's vantage point roughly 10,000 light years away.

By combining the X-ray data with some 30 years of observations in radio waves with the VLA, astronomers have also produced a movie, using three different images. Astronomers have used these X-ray and radio data to learn new things about this supernova and its remnant.

The researchers measured the speed of the blast wave at many different locations around the remnant. The large size of the remnant enables this motion to be measured with relatively high precision. Although the remnant is approximately circular, there are clear differences in the speed of the blast wave in different regions. The speed in the right and lower right directions is about twice as large as that in the left and the upper left directions. This difference was also seen in earlier observations.

This range in speed of the blast wave's outward motion is caused by differences in the density of gas surrounding the supernova remnant. This causes an offset in position of the explosion site from the geometric center, determined by locating the center of the circular remnant. The astronomers found that the size of the offset is about 10% of the remnant's current radius, towards the upper left of the geometric center. The team also found that the maximum speed of the blast wave is about 12 million miles per hour.

Offsets such as this between the explosion center and the geometric center could exist in other supernova remnants. Understanding the location of the explosion center for Type Ia supernovas is important because it narrows the search region for a surviving companion star. Any surviving companion star would help identify the trigger mechanism for the supernova, showing that the white dwarf pulled material from the companion star until it reached a critical mass and exploded. The lack of a companion star would favor the other main trigger mechanism, where two white dwarfs merge causing the critical mass to be exceeded, leaving no star behind.

The significant offset from the center of the explosion to the remnant's geometric center is a relatively recent phenomenon. For the first few hundred years of the remnant, the explosion's shock was so powerful that the density of gas it was running into did not affect its motion. The density discrepancy from the left side to the right has increased as the shock moved outwards, causing the offset in position between the explosion center and the geometric center to grow with time. So, if future X-ray astronomers, say 1,000 years from now, do the same observation, they should find a much larger offset.

A paper describing these results has been accepted for publication in The Astrophysical Journal Letters and is available online. The authors are Brian Williams (NASA's Goddard Space Flight Center), Laura Chomiuk (Michigan State University), John Hewitt (University of North Florida), John Blondin (North Carolina State University), Kazimierz Borkowski (NCSU), Parviz Ghavamian (Towson University), Robert Petre (GSFC), and Stephen Reynolds (NCSU).

NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory in Cambridge, Massachusetts, controls Chandra's science and flight operations.

Fast Facts for Tycho's Supernova Remnant:

Scale: Image is 15 arcmin across (about 44 light years)
Category: Supernovas & Supernova Remnants
Observation Date: 13 pointings between 2000 and 2015
Observation Time: 325 hours 17 min (13 days 13 hours 17 min)
Obs. ID: 115, 3837, 7639, 8551, 10093-10097; 10902-10904; 10906, 15998
Instrument: ACIS
Also Known As: G120.1+01.4, SN 1572
References: Williams, B. et al, 2016, ApJL (accepted); arXiv:1604.01779
Color Code: X-ray (Red 0.95-1.26 keV, Green 1.63-2.26 keV, Blue 4.1-6.1 keV), Optical (Red, Green, Blue)
Distance Estimate: About 13,000 light years

Source: NASA’s Chandra X-ray Observatory