Located 12 million light-years away and undergoing rapid star formation,
edge-on spiral galaxy Messier 82 (M82) is a scientifically unique sight to
behold, and now NASA’s James Webb Space Telescope has revealed previously
unseen details.
M82’s intense star formation,
thought to be the result of a galaxy merger, will be a short-lived event in
astronomical terms, estimated to last a few hundred million years in its
entirety. This temporary phase of extreme star formation relative to the galaxy’s
mass, as well as its location in the local universe, are among the factors that
make M82, also known as the Cigar galaxy, a one-of-a-kind environment to study.
Image: M82 Cigar Galaxy (Webb + Hubble)
Scientists used NASA’s James Webb Space Telescope to
image edge-on starburst galaxy Messier 82 and trace its evolutionary history.
This Webb and Hubble composite image includes 16.5 million stars (blue-white),
dust grains (red-orange), and ionized hydrogen gas (yellow).
Image: NASA, ESA, CSA, Adam Smercina (STScI, Tufts),
Thomas Williams (University of Manchester); Image Processing: Alyssa Pagan
(STScI)
A team of astronomers recently
completed an imaging survey with the Webb telescope. This program entailed a total of 65 hours of observation time
with Webb’s NIRCam
(Near-Infrared Camera) instrument and revealed never-seen-before details of the starburst galaxy, including its distended disk structure and millions
of individual stars. Webb’s high-resolution imaging, specifically of the main
plane of the galactic disk, has unlocked vital information for astronomers as
they seek to uncover M82’s formation history. Additionally, the Webb data will
help scientists understand the current processes occurring within the starburst
galaxy.
“M82 is a mess, but it’s a
beautiful mess. We don’t fully understand what’s going on, especially
concerning its evolutionary history. What could have triggered such an elevated
rate of star formation? How long has this galaxy been driving plumes of material
away from its center?” said principal investigator Adam Smercina, a NASA Hubble
Fellow at the Space Telescope Science Institute in Baltimore, and incoming
Assistant Professor at Tufts University in Massachusetts. “M82 is an ideal
galaxy evolution laboratory because it has properties that allow us to probe
important physical processes, such as how stars form in such environments and
how that activity drives outflows. M82 provides a simultaneous window onto many
astrophysical questions, in a way that no other galaxy in the local universe
can.”
Image: M82 Cigar Galaxy (NIRCam
Image)
NASA’s James Webb Space Telescope observed edge-on
starburst galaxy Messier 82, peering through dust to reveal 16.5 million stars
and the galaxy’s distended disk structure. Scientists seek to learn the
galaxy’s evolutionary history with the Webb data.
Image: NASA, ESA, CSA, Adam Smercina (STScI, Tufts),
Thomas Williams (University of Manchester); Image Processing: Alyssa Pagan
(STScI)
Prior to Webb, many observatories
looked at the starburst galaxy, including NASA’s Hubble and retired Spitzer space telescopes. However, the sheer volume of
dust within that galaxy limited the amount of information astronomers could
acquire on M82 at high resolution. While Webb has previously looked at this galaxy, the duration of the new imaging survey, combined
with the telescope’s infrared sensitivity, enabled it to pierce through the
thick dust.
Image: M82 Cigar Galaxy
(Hubble/Webb Side-by-Side)
Side-by-side comparison of a portion of starburst
galaxy Messier 82 (M82) as seen by NASA’s Hubble (left) and James Webb (right)
space telescopes. Hubble detailed M82’s gas and dust structure, while Webb
pierced through the dust and resolved millions of stars in infrared light.
Image: NASA, ESA, CSA, Adam Smercina (STScI, Tufts),
Thomas Williams (University of Manchester); Image Processing: Alyssa Pagan
(STScI)
The telescope’s near-infrared-light
view is a snapshot of a scene that has been evolving over a couple hundred
million years. Webb’s image contains approximately 16.5 million individual
stars dispersed throughout the galaxy. The light from these stellar sources is
depicted as luminous blue granules. This is only a small portion of the total
amount of stars astronomers think reside in a galaxy like M82, with the
majority too faint to be seen.
“The sheer number of stars that we
were able to resolve with Webb is incredible,” said team member Benjamin
Williams of the University of Washington. “It’s a whole different world from
what we’ve been able to see with other telescopes. All of these stars
collectively provide a detailed fossil record of the formation and evolution of
M82.”
Moving inward, the increase in
brightness and the asymmetrical shape of the galactic disk hints at the spiral
galaxy’s unique underlying structure. The differing radii between the two sides
suggests that M82 has a distorted shape, which can happen during intense galaxy
mergers.
“At first glance, the disk of the
galaxy may seem less spectacular because Webb sees through the dust,” said team
member Eric Bell of the University of Michigan. “But M82 is a delightfully
complex system. Webb’s observations will help us address some ongoing
mysteries, such as how star formation has moved within M82 over the last few
billion years.”
Video: M82
Cigar Galaxy (Webb + Hubble Fade)
NASA’s James Webb Space Telescope’s near-infrared
observation of M82 is the most recent addition to overall data on this
starburst galaxy. The Hubble Space Telescope is one observatory that has
previously looked at M82, detailing the gas and dust structure seen in visible
light.
Video: NASA, ESA, CSA, STScI,
Alyssa Pagan (STScI)
Because of the extreme star formation
within the galaxy, which is 10 times faster than the Milky Way galaxy’s star
formation rate, stellar birth will eventually be disrupted. M82’s stellar
frenzy is causing bipolar plumes of material to be ejected above and below the
disk. Though it looks like a tumultuous region, the hourglass-shaped outflows
appear to have a layered structure. The yellow tendrils of material closest to
the galaxy’s disk represent ionized gas, whereas the orange material farther
away depicts small dust grains. These grains are called polycyclic aromatic
hydrocarbons and are helpful in tracing material in the space between the
galaxy’s stars, also known as the interstellar medium.
The information collected as part of
this Webb study is just one dataset scientists will analyze as they seek to
piece together this starburst galaxy’s formation history.
“Galaxies are such intricate ecosystems
that if you truly want to understand them, you have to pull datasets from
different missions together,” said team member Kristen McQuinn of the Space
Telescope Science Institute. “One mission cannot fully answer all of the
questions we have about M82. Combining the data collected by different
telescopes, like Webb and Hubble, is powerful. When you marry the datasets, you
expand what you can probe, and the questions that you can pose are even more
complex.”
The James Webb Space Telescope is the
world’s premier space science observatory. Webb is solving mysteries in our
solar system, looking beyond to distant worlds around other stars, and probing
the mysterious structures and origins of our universe and our place in it. Webb
is an international program led by NASA with its partners, ESA (European Space
Agency) and CSA (Canadian Space Agency).
To learn more about Webb, visit: https://science.nasa.gov/webb
Source: NASA’s Webb Pinpoints Millions of Stars Within Cigar Galaxy - NASA Science



