In the vast expanse of the universe, astronomers continue to uncover fascinating celestial phenomena. A collaborative team from the Massachusetts Institute of Technology and Penn State University has recently made a groundbreaking discovery of an exoplanet named TIC 241249530 b. This planet is in the process of evolving into a hot Jupiter, a type of gas giant that orbits very close to its star. The findings, published in the journal Nature, offer valuable insights into the life cycle of such extreme planets.
Located approximately 1,100 light-years from Earth, TIC 241249530 b orbits its star in a highly eccentric path. This means that its orbit is elongated, causing the planet to come extremely close to the star before swinging far away. If it were part of our solar system, TIC 241249530 b would pass within 10 times the distance of Mercury from the Sun, then stretch out to a distance just beyond Earth. This unique orbit showcases the highest eccentricity of any known planet, which has intrigued scientists and prompted further investigation into its origins.
One particularly striking feature of TIC 241249530 b is its retrograde orbit. Unlike the planets in our solar system, which orbit in the same direction as the Sun’s rotation, this new planet travels in the opposite direction. This unusual orientation, combined with its eccentricity, suggests that TIC 241249530 b is undergoing a process called high-eccentricity migration. This phenomenon occurs when a planet's orbit shifts dramatically due to gravitational interactions with other celestial bodies. In this case, the planet orbits a star that is part of a binary system, where two stars influence each other's movements.
The research team, led by MIT physicist Sarah Millholland, conducted simulations to understand how TIC 241249530 b's orbit evolved over time. Their findings indicate that the planet likely formed as a cold Jupiter, far from its star, in a region where temperatures were low enough for it to condense and take shape. Over billions of years, interactions with the secondary star in its binary system caused the planet's orbit to become increasingly eccentric, ultimately leading it on a path toward becoming a hot Jupiter.
Currently, TIC 241249530 b takes about 167 days to complete one orbit around its star. However, researchers predict that in approximately 1 billion years, it will transition into a tighter, circular orbit, completing its journey to becoming a hot Jupiter. At that point, the planet will experience extreme temperatures, potentially reaching several thousand kelvins, as it orbits closely around its host star.
The discovery of TIC 241249530 b is significant, as it supports the theory that high-eccentricity migration plays a crucial role in the formation of hot Jupiters. This research not only sheds light on the processes that govern planetary evolution but also highlights the diversity of exoplanets and their unique orbital characteristics. Millholland emphasizes that this discovery provides a clearer understanding of how planets can transition from cold to hot states over astronomical timescales.
The planet was first detected using data from NASA’s Transiting Exoplanet Survey Satellite (TESS), an MIT-led mission designed to monitor nearby stars for signs of transiting planets. The collaborative effort between MIT and Penn State University, along with other institutions, underscores the importance of interdisciplinary research in advancing our understanding of the cosmos. As astronomers continue to study TIC 241249530 b and its peculiar characteristics, they hope to unlock further secrets about the formation and evolution of planets in our galaxy.