Artist’s illustration of cosmic ray-driven winds (blue and inexperienced) superimposed on a visible-light picture of the Triangulum galaxy M33 (pink and white) noticed with VLT Survey Telescope at ESO’s Paranal Observatory in Chile. Credit: Institute for Research in Fundamental Sciences- IPM & European Southern Observatory (ESO)
The examine reveals cosmic rays are driving galaxies’ winds
An necessary new trace relating to how galaxies halt intense episodes of star formation has been discovered by astronomers utilizing the Karl G. Jansky Very Large Array (VLA) of the National Science Foundation. Their latest analysis on the close by galaxy M33 means that quick cosmic ray electrons can generate winds that blow away the gasoline required for the formation of latest stars.
As galaxies evolve over time, these winds are what trigger the star formation fee to decelerate. However, the first sources of such winds have been attributed to materials jets powered by black holes and shock waves from supernova explosions. Cosmic rays have been assumed to be small contributors, particularly in galaxies with prolific star formation, akin to M33.
“We have seen galactic winds pushed by cosmic rays in our personal Milky Way and the Andromeda galaxy, which have much weaker rates of star formation, but not before in a galaxy such as M33,” said Fatemah Tabatabaei, of the Institute for Research in Fundamental Sciences in Iran.
M33 is a spiral galaxy that is almost 3 million light-years distant and is a member of the Local Group of galaxies, which also contains the Milky Way. Tabatabaei and an international team of scientists made detailed, multi-wavelength VLA observations of M33. Additionally, they made use of information gathered from earlier observations made with the VLA, the German Effelsberg radio telescope, millimeter-wave, visible-light, and infrared telescopes.
Stars much larger than our Sun speed through their life cycles, eventually exploding as supernovae. Cosmic rays are produced when explosive shock waves accelerate particles almost to the speed of light. If there are enough of these cosmic rays, pressure can be created that drives winds that transport away the gas required for star formation.
“The VLA observations indicated that cosmic rays in M33 are escaping the regions where they are born, making them able to drive more extensive winds,” said William Cotton, of the National Radio Astronomy Observatory.
Based on their observations, the astronomers concluded that the numerous supernova explosions and supernova remnants in M33’s giant complexes of prolific star formation made such cosmic ray-driven winds more likely.
“This means that cosmic rays probably are a more general cause of galactic winds, particularly at earlier times in the universe’s history, when star formation was happening at a much higher rate,” Tabatabaei said. She added, “This mechanism thus becomes a more important factor in understanding the evolution of galaxies over time.”
Reference: “Cloud-scale radio surveys of star formation and feedback in Triangulum Galaxy M 33: VLA observations” by F. S. Tabatabaei, W. Cotton, E. Schinnerer, R. Beck, A. Brunthaler, K. M. Menten, J. Braine, E. Corbelli, C. Kramer, J. E. Beckman, J. H. Knapen, R. Paladino, E. Koch, A. Camps Fariña, 25 October 2022, Monthly Notices of the Royal Astronomical Society.
DOI: 10.1093/mnras/stac2514
The study was funded by the National Science Foundation.
The National Radio Astronomy Observatory is a facility of the National Science Foundation, operated under a cooperative agreement by Associated Universities, Inc.
