This new movie of X-ray data from Chandra of the supernova remnant
Cassiopeia A (Cas A) was made by combining observations taken in
January 2000, February 2002, February 2004, and December 2007. In these
images, the lowest-energy X-rays Chandra detects are shown in red, intermediate
energies in green, and the highest energies in blue. Scientists
have used the movie to measure the expansion velocity of the leading edge of the
explosion's outer blast wave (shown in blue). The researchers find
that the velocity is 11 million miles per hour, which is significantly
slower than expected for an explosion with the energy estimated to have been
released in Cas A.
This slower velocity is explained by a special type of energy loss
by the blast wave. Electrons are accelerated to high energies as they travel
backwards and forwards across the shock front produced by the blast
wave. As the electrons travel around magnetic fields in the shock
they lose energy by producing synchrotron emission and glowing in X-rays.
Scientists think heavier particles like protons and ions are accelerated
in the same way. The energy lost by these heavier particles can amount
to a large fraction of the energy from the supernova explosion, resulting in a
slower shock velocity. The accelerated protons and ions which escape from
the remnant are known as "cosmic rays", and continually bombard the
Earth's atmosphere. Supernova remnants are believed to be one of the main
sources of cosmic rays.
The authors have constructed a model that combined the measured
expansion velocity, as well as its observed size, with estimates of the
explosion energy, the mass of the ejected material in Cas A and efficient
particle acceleration. For everything to agree, about 35% of the energy of
the Cas A supernova went into accelerating cosmic rays.
Another new feature seen in the Cas A movie is "flickering" of the
blue synchrotron emission seen on timescales of about a year. This
flickering is thought to be a direct result of acceleration of particles to
high energies, causing the emission to become brighter, followed by rapid
cooling, causing the emission to fade. These variations provide
important clues about the location of the acceleration, a topic of some
controversy. For the first time, this flaring is seen in the outer
blast wave. This casts doubt upon the possibility, suggested previously,
that cosmic ray acceleration occurs in the so-called "reverse shock".
This is a shock that travels backwards into the expanding remnant and is
therefore located inside the outer blast wave. Previous claims that flaring
occurs in the reverse shock may simply have been caused by regions in the
outer blast wave that are projected onto the middle of the
two-dimensional image.
The rapid flickering not only gives information about acceleration of
particles to high energies, but it also shows that relatively strong
magnetic fields have been generated in the shock front.
Fast Facts for Cassiopeia A: |
Credit |
NASA/CXC/SAO/D.Patnaude et al. |
Release Date |
January 6, 2009 |
Scale |
Image is 8.4 arcmin across |
Category |
Supernovas & Supernova Remnants |
Coordinates (J2000) |
RA | Dec |
Constellation |
Cassiopeia |
Observation Date |
01/30/2000 - 12/08/2007 with 5 pointings
|
Observation Time |
56 hours |
Obs. ID |
114, 1952, 5196, 9117, 9773
|
Instrument |
ACIS
|
Also Known As | Cas A |
Color Code |
Energy (Red (0.5-1.5 keV); Green (1.5-3.0 keV); Blue (4.0-6.0 keV)) |
Distance Estimate |
About 11,000 light years
|
|