After defending his PhD thesis on modeling interstellar objects on Monday, June 30, Matthew Hopkins intended to take some well-deserved time off. It would appear the universe had other plans for him.
The very next day, the Atlas Terrestrial-impact Last Alert System (ATLAS) telescope in Rio Hurtado, Chile, detected a mysterious object whizzing toward the Sun. Early observations suggested that it came from outside our solar system, potentially marking the third discovery of an interstellar object in history. Astronomers across the globe—including Hopkins—leapt into action, racing to gather as much data on this wandering space rock as they could. By Thursday, July 3, the International Astronomical Union’s Minor Planet Center confirmed that an interstellar object was, indeed, traveling through our cosmic neighborhood, naming it 3I/ATLAS. Now, Hopkins and his colleagues believe they know where it came from.
“It’s very exciting!” Hopkins, an astrophysics graduate student at the University of Oxford, told IFLScience. “I’ve been anticipating the chance to compare my predictions to new data for four years, and 3I/ATLAS is already giving us new insights into this fascinating galaxy-spanning population.”
Through preliminary observations, astronomers have learned a lot about 3I/ATLAS. It’s the largest and brightest interstellar object yet, according to Space.com. Experts are fairly confident that it’s a comet zipping through our solar system at incredibly high speeds. Upon its discovery, the object was traveling 137,000 miles per hour (221,000 kilometers per hour), and it will speed up as it approaches the Sun. 3I/ATLAS appears to be much bigger than the two interstellar objects that came before it: ‘Oumuamua and Comet 2I/Borisov. Early size estimates suggest it could be 6 to 19 miles (10 to 30 kilometers) wide. Don’t worry, there’s no chance of this space rock hitting our planet, but it will safely make its closest approach to Earth on October 30.
Initial spectroscopy suggests 3I/ATLAS is redder in color than typical solar system comets, similar to some trans-Neptunian objects—minor planets that orbit the Sun beyond Neptune’s orbit—or tiny, icy celestial bodies located between Jupiter and Neptune called Centaurs. Another study made photometric observations of the object that found it to be similar in color to some solar system comets but markedly bluer than ‘Oumuamua and 2I/Borisov.
Together, these early findings paint a vivid picture of our solar system’s latest guest, but figuring out where this comet came from is equally as important as figuring out what it looks like. Interstellar objects like this one are “pristine, primordial remnants from the planet formation process in other planetary systems,” Darryl Seligman, an associate professor of physics and astronomy at Michigan State University, wrote in an article for The Conversation. Understanding 3I/ATLAS’s origin would allow astronomers to extrapolate information about how planets form in this foreign star system.
To that end, Hopkins and his colleagues analyzed 3I/ATLAS using the Otautahi-Oxford model. This new model integrates data from the European Space Agency’s (ESA) Gaia observatory with models of protoplanetary disk chemistry and galactic dynamics to predict the distributions of velocities, ages, and compositions across the interstellar object population in our cosmic neighborhood. Hopkins and several of his co-authors contributed to the development of Otautahi-Oxford.
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