These large gaseous exoplanets — planets outside our solar system — can make their suns wobble when they wend their way through their own solar systems to snuggle up against their suns, according to new Cornell University research.
“Although the planet’s mass is only one-thousandth of the mass of the Sun, the stars in these other solar systems are being affected by these planets and making the stars themselves act in a crazy way,” said Dong Lai from Cornell.
In our solar system, the Sun’s rotation axis is approximately aligned with the orbital axis of all the planets. The orbital axis is perpendicular to the flat plane in which the planets revolve around the Sun. In solar systems with hot Jupiters, recent observations have revealed that the orbital axis of these planets is misaligned with the rotation axis of their host star. In the last few years, astronomers have been puzzled by spin-orbit misalignment between the star and the planets.
Roasting like marshmallows on an open fire, hot Jupiters — large gaseous planets dispensed throughout the universe in other solar systems — wander from distant places to orbit extraordinarily close to their own suns. Partner binary stars, some as far as hundreds of astronomical units — an astronomical unit is 93 million miles (150 million kilometers), the distance between Earth and the Sun — influence through gravity the giant Jupiter-like planets and cause them to falter into uncommon orbits; that, in turn, causes them to migrate inward close to their sun, Lai said.
“When exoplanets were first found in the 1990s, it was large planets like Jupiter that were discovered. It was surprising that such giant planets can be so close to [their] parent star,” Lai said. “Our own planet Mercury is very close to our Sun. But these hot Jupiters are much closer to their suns than Mercury.”
By simulating the dynamics of these exotic planetary systems, the Cornell astronomers showed that when the Jupiter-like planet approaches its host star, the planet can force the star’s spin axis to precess — change the orientation of its rotational axis — much like a wobbling, spinning top.
“Also, it can make the star’s spin axis change direction in a rather complex or even a chaotic way,” said Lai. “This provides a possible explanation to the observed spin-orbit misalignments and will be helpful for understanding the origin of these enigmatic planets.”
Another interesting feature of the Cornell work is that the chaotic variation of the star’s spin axis resembles other chaotic phenomena found in nature, such as weather and climate.