A team of astronomers has detected a repeating radio signal from a planet orbiting a nearby star. The movement is the first of its kind ever observed from an exoplanet, and it could provide clues about the planet’s magnetic field and atmosphere.
How did they find the signal?
The researchers used a radio telescope, LOFAR (Low-Frequency Array), to observe a star system called Tau Boötis, located about 51 light-years away from Earth. The system consists of a sun-like star and a hot Jupiter, a gas-giant planet that orbits very close to its star.
Previous studies have shown that the planet, Tau Boötis b, is tidally locked to its star, meaning it always shows the same face to its host. This creates extreme temperature differences between the day and night sides of the planet, which could drive strong winds and generate a powerful magnetic field.
The astronomers were looking for radio emissions from the planet’s magnetic field, which could interact with the star’s wind and produce detectable signals. They found that the earth emits a radio signal every 11.4 hours, corresponding to its orbital period. The password is about 100 times stronger than any radio emission from Jupiter.
What does the signal mean?
The signal is a sign that the planet has a magnetic field, which is rare among exoplanets. Only a few exoplanets have been confirmed to have magnetic fields, and radio observations have detected none.
“This is an exciting discovery because it shows that we can use radio astronomy to probe the atmospheres and interiors of exoplanets,” said Dr. Jake Turner, the study’s lead author and an astronomer at Cornell University. “We can learn about their magnetic fields, climates, and origins.”
The signal also reveals information about the planet’s atmosphere, which is thought to be mostly hydrogen and helium. The researchers estimate that the atmosphere has a temperature of about 2,000 degrees Celsius on the day side and 1,000 degrees Celsius on the night side. The atmosphere also has a pressure of about 10 bars at the surface, which is ten times higher than Earth’s.
What are the implications of the discovery?
The discovery opens up new possibilities for studying exoplanets with radio telescopes. The researchers hope to use LOFAR and other instruments to search for more radio signals from other exoplanets, especially potentially habitable ones.
“We are only scratching the surface of what we can learn from radio observations of exoplanets,” said Dr. Jean-Mathias Grießmeier, a study co-author and an astronomer at Paris Observatory. “There are many more planets out there waiting to be discovered and explored.”
Their findings are published in the journal Nature Astronomy.
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