Dust cloud determines distance

June 01, 2021
Some of the most energetic radiation that reaches Earth comes from an exploded star in our Galaxy. An international team of researchers was now able to measure the distance to this object using an adjacent dust cloud with much higher degree of precision than ever before. This is the first step in better understanding the energetic processes that are going on in this supernova remnant.

Normally, what you see in the sky are bright objects, and these are also easy to spot with telescopes. However, sometimes astronomers take a different view and look at objects that are detectable through their shadow. An international team of researchers from Australia, Germany, Italy, Japan, and the USA have now focused on dust in the remains of an exploded star (also called a supernova remnant, SNR in short). This object, with the name RX J1713.7-3946, is one of the brightest emitters of very high-energy radiation and the origin of this has been debated since its discovery.

Rather than investigating the high-energy radiation directly, the scientists investigated the shadows cast by intergalactic dust clouds on stars in the background. They reconstructed the dust extinction in the region of the SNR using a Gaussian process and more than 260 000 stars. While the resulting map indicates the presence of several clouds along the line of sight, only one of the clouds appears to be in the vicinity of the exploded star.

By using distance estimates to the individual stars in the direction of RX J1713.7-3946 provided by the European Space Agency Gaia space mission, the researchers were able to constrain the distance to the dust cloud, and therefore to the supernova remnant, to a 1% accuracy, about 20 times more precisely than previous estimates.

This is an important milestone, as it helps to understand the energetic processes taking place at and around the supernova remnant. Precise distances are among the most challenging measurements in Astronomy. Without their knowledge, it is impossible to be sure whether an object is intrinsically brighter and further away, or intrinsically fainter but closer.

A precise distance determination is crucial for this supernova remnant, as it is at the origin of some of the highest energy photons that we see on Earth. Yet, the mechanism by which these photons (or gamma-rays) are generated is still not fully understood. One possible explanation for the high-energy radiation are proton-proton collisions, but previous estimates of the gas content fell short. With an estimated mass of about 7000 times the mass of the Sun, the dust cloud could be big enough to contain the missing protons, but further studies are needed to confirm this.

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