Magnetic Fields Force New Perspective on the Center of Our Milky Way Galaxy
The area around the supermassive black hole at the center of our Milky Way galaxy is dominated by gravity, but it’s not the only force at play. According to new research from NASA’s airborne telescope, the Stratospheric Observatory for Infrared Astronomy, or SOFIA, magnetic fields may be strong enough to control material moving around the black hole.
A composite image of the central region of our Milky Way galaxy, known as Sagittarius A. SOFIA found that magnetic fields, shown as streamlines, are strong enough to control the material moving around the black hole, even in the presence of enormous gravitational forces. This can help answer long-standing, fundamental questions about the galactic center region: why the star formation rate is significantly lower than expected and why our galaxy’s black hole is quieter than those in other galaxies. SOFIA data is shown in green (37 microns) and dark blue (25 and 53 microns). The light blue is from Herschel Space Observatory (70 microns) and the gray is from the Hubble Space Telescope.
The research, presented this week at a meeting of the American Astronomical Society, could help answer longstanding mysteries about why our black hole is relatively quiet compared to others, and why the formation of new stars in our galaxy’s core is lower than expected.
Using its newest infrared instrument to study celestial dust grains, which align perpendicular to magnetic field lines, SOFIA was able to produce detailed maps of our galactic center, showing the behavior of these otherwise invisible magnetic fields around the black hole.
“There are still aspects of our galaxy’s black hole that we can’t explain with gravity alone,” said Joan Schmelz, SOFIA senior science advisor and director at the Universities Space Research Association, in Columbia Maryland. “Magnetic fields may be able to help solve these mysteries.”
Scientists have often relied on gravity to explain their results because measuring celestial magnetic fields is extremely challenging. But the data from SOFIA now compel scientists to consider their role. Magnetic fields control the plasma of the solar atmosphere, called the corona, because the pressure created by magnetic fields is greater than the pressure created by heat, or thermal pressure. In the Sun’s corona, the dominance of magnetic pressure creates dramatic loops and powerful flares. The research team is using SOFIA’s data to study the pressure created by magnetic fields at the center of our galaxy. They found that the magnetic pressure is greater than the thermal pressure created by gas in the region, and therefore may be strong enough to control matter in a way that’s similar to the solar corona.
More research is needed to understand magnetic fields’ role at the center of our galaxy and how these strong forces fit in with gravity. However, these preliminary results can enhance our understanding of at least two long-standing, fundamental questions about star formation and black hole activity in our galactic center region. Even though there’s plenty of raw material to form stars, the star formation rate is significantly lower than expected. Additionally, our black hole is relatively quiet compared to those at the centers of many other galaxies. The strong magnetic field could explain both — it could keep the black hole from swallowing the matter it needs to form jets and also suppress the birth of stars.
Studying magnetic fields in the far reaches of the galaxy and beyond requires remote observations by telescopes like SOFIA. Flying at an altitude of 45,000 feet, above 99% of the Earth’s water vapor, SOFIA is able to capture a unique view of the infrared universe, while landing after each flight so that it can be upgraded with the latest technology. For this result, SOFIA used the High-resolution Airborne Wideband Camera-Plus, or HAWC+ instrument, which was built at NASA’s Jet Propulsion Laboratory in Pasadena, California, to study magnetic fields.
“The data provide the most detailed look yet at the magnetic fields surrounding our galaxy’s central black hole,” said David Chuss, a coauthor of the paper at Villanova University in Pennsylvania. “The HAWC+ instrument has improved the resolution by a factor of 10 and increased the sensitivity, which represent a revolutionary step forward.”
Source: U.S. National Aeronautics and Space Administration
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