New images of cigar-shaped M82 galaxy capture millions of stars
The Messier 82 galaxy, known as M82 or the Cigar galaxy, has long fascinated researchers with its astronomical rate of star formation — approximately 10 times faster than the Milky Way. Researchers have pored over grainy, low-resolution, images taken by previous generations of telescopes, which weren’t powerful enough to see through the thick cloud of dust surrounding the galaxy. The , however, can pierce straight through with extremely sharp vision. That enabled a team of astronomers from multiple institutions, including NASA and the UW, to capture new high-resolution images. Posted June 23, the images include more than 16.5 million individual stars and provide the clearest look yet at M82’s , the flattened central hub that contains most of the galaxy’s stellar mass. That could help scientists understand how M82 formed and for how long it has been producing stars so prodigiously.
For more information, contact team member a UW research professor of astronomy, at benw1@uw.edu.
All images are included in NASA’s
New study maps pollution disparities by state and sector across almost 20 years
Air quality in the United States has improved markedly since the landmark Clean Air Act passed in 1970. However, the gains have not been equally shared: Today, communities of color and low-income communities are exposed to disproportionately more air pollution than the overall population. In in Science Advances, UW researchers created the first comprehensive map cataloging how air quality inequity has changed per state and economic sector from 2002 to 2019. The study confirmed that, despite improvements in overall air quality, pollution tends to be concentrated in Black, Hispanic and low-income communities. The findings include specific state-level opportunities for improvement across 11 sectors — for example, disparities in construction-related emissions in Florida increased significantly during the study period. The findings and resulting database could help policymakers across the country prioritize environmental justice projects.
For more information, contact senior author , UW professor of civil and environmental engineering at jdmarsh@uw.edu.
The other UW co-authors are , , and . A full list of co-authors is .Ìý
Researchers observe ultrafast chemistry happening in real time
Molecules are not static. Instead, they are having little dance parties — their atoms wiggle and twist around in space. Occasionally, upon receiving a burst of energy, the bonds holding atoms together in a molecule can break and reform with the atoms in a different configuration. While the number of atoms stays the same, the orientation of these atoms determines a molecule’s chemical properties — an important part of its identity. In , a UW-led team witnessed firsthand, and for the first time, a molecule turning into its “alter ego.” The researchers observed a hydrogen atom, also known as a proton, jump to a new position by bonding to a different atom in the same molecule. This process, which happens within a few millionths of billionths of a second, is important for various fundamental processes, including photosynthesis, and when DNA acquires mutations. To understand why, and how, this happens so fast, the researchers developed a new tool that probes molecular structure on an ultrafast timescale. They were able to use this technology to detect how the molecule’s wiggles allowed the proton transfer to happen. These findings will help researchers test existing theories about these ultrafast chemical dynamics and develop new molecules for clean energy processes.
For more information, contact senior author , UW professor of chemistry, at mkhalil@uw.edu.ÌýÌýÌý
Co-authors , and completed this work while at the UW. Funding information is .
Random events leave lasting signature on the atmospheric methane record, new study shows
Methane is a powerful greenhouse gas with a complicated life cycle. It’s released into the atmosphere by both natural and industrial processes, and there are multiple pathways by which it’s broken down. Recently, atmospheric methane levels have reached record highs but the rate of accumulation has been somewhat inconsistent over time. To understand why, researchers are looking at climate records preceding the industrial era, via ice cores. These deep cylinders of glacial ice document slow swings in atmospheric methane levels spanning decades, or even centuries. This pattern is typically associated with gradual climate change, but in , UW researchers show that it doesn’t have to be. Instead, they reveal that short-term, random events, such as fires or changes in wetlands, can spark gradual shifts. Not only does this clarify the historical record, but it also adds nuance to modern trends.
For more information, contact senior author , UW doctoral student of atmospheric and climate science at emei@uw.edu.
The other UW co-authors are and . A full list of co-authors is .