On the left is the starburst galaxy M82 as observed by NASA’s Hubble Space Telescope in 2006. The small box at the galaxy’s core corresponds to the area captured so far by the NIRCam (Near-Infrared Camera) instrument on NASA’s James Webb Space Telescope. The red filaments as seen by Webb are the polycyclic aromatic hydrocarbon emission, which traces the shape of the galactic wind. In the Hubble image, light at .814 microns is colored red, .658 microns is red-orange, .555 microns is green, and .435 microns is blue (filters F814W, F658N, F555W, and F435W, respectively). In the Webb image, light at 3.35 microns is colored red, 2.50 microns is green, and 1.64 microns is blue (filters F335M, F250M, and F164N, respectively). Credit: NASA, ESA, CSA, STScI, A. Bolatto (University of Maryland).

An international team of astronomers has used NASA’s James Webb Space Telescope (JWST) to survey the starburst galaxy Messier 82 (M82). Located 12 million light-years away in the constellation Ursa Major, this galaxy is relatively compact in size but hosts a frenzy of star formation activity and is sprouting new stars 10 times faster than the Milky Way galaxy.

Dr Deanne Fisher from Swinburne University of Technology’s Centre of Astrophysics and Supercomputing led the Australian team, directing the JWST’s NIRCam (Near-Infrared Camera) instrument toward the starburst galaxy’s center to obtain a closer look at the physical conditions that foster the formation of new stars.

“The James Webb Space Telescope really opens a new window to studying the gas in galactic winds. We can now see the tiny building blocks of the wind,” Dr Fisher says.

The JWST’s NIRCam instrument was well-suited to trace the structure of the galactic wind via emission from sooty chemical molecules known as polycyclic aromatic hydrocarbons (PAHs). PAHs can be considered as very small dust grains that survive in cooler temperatures but are destroyed in hot conditions.

Much to the team’s surprise, the JWST’s view of the PAH emission highlights the galactic wind’s fine structure – an aspect previously unknown. Depicted as red filaments, the emission extends away from the central region where the heart of star formation is located. Another unanticipated find was the similar structure between the PAH emission and that of hot, ionised gas.

“The PAH emission is an exciting new tool,” explains Dr Fisher. “PAHs are very fragile. You would expect that when supernovae expose the hot inner material from stars, they would obliterate the colder gas.”

“The fact that the PAHs seem to survive out into the wind is a real challenge to theory. It means there is extra physics that we need to understand. Interestingly we think that similar physics that shapes clouds in the sky, or waves in water, may be important in these extreme environments of galactic winds.”

 Finding structure in lively conditions

Looking at M82 in slightly longer infrared wavelengths, clumpy tendrils represented in red can be seen extending above and below the galaxy’s plane. These gaseous streamers are a galactic wind rushing out from the core of the starburst.

One area of focus for this research team was understanding how this galactic wind, which is caused by the rapid rate of star formation and subsequent supernovae, is being launched and influencing its surrounding environment. By resolving a central section of M82, scientists could examine where the wind originates, and gain insight on how hot and cold components interact within the wind.

A vibrant community of stars

Star formation continues to maintain a sense of mystery because it is shrouded by curtains of dust and gas, creating an obstacle in observing this process. Fortunately, the JWST’s ability to peer in the infrared is an asset in navigating these murky conditions. Additionally, these NIRCam images of the very center of the starburst were obtained using an instrument mode that prevented the very bright source from overwhelming the detector.

While dark brown tendrils of heavy dust are threaded throughout M82’s glowing white core even in this infrared view, the JWST’s NIRCam has revealed a level of detail that has historically been obscured. Looking closer toward the center, small specks depicted in green denote concentrated areas of iron, most of which are supernova remnants. Small patches that appear red signify regions where molecular hydrogen is being lit up by a nearby young star’s radiation.

Lighting a path forward 

The JWST’s observations of M82 in near-infrared light spur further questions about star formation, some of which the team hopes to answer with additional data gathered with the JWST, including that of another starburst galaxy. Two other papers from this team characterizing the stellar clusters and correlations among wind components of M82 are almost finalized.

In the near future, the team will have spectroscopic observations of M82 from the JWST ready for their analysis, as well as complementary large-scale images of the galaxy and wind. Spectral data will help astronomers determine accurate ages for the star clusters and provide a sense of timing for how long each phase of star formation lasts in a starburst galaxy environment. On a broader scale, inspecting the activity in galaxies like M82 can deepen astronomers’ understanding of the early universe.

These findings have been accepted for publication in The Astrophysical Journal.

Video: The starburst galaxy M82 as observed by NASA’s Hubble Space Telescope and NASA’s James Webb Space Telescope. Credits: NASA, ESA, CSA, STScI, A. Bolatto (University of Maryland)