Researchers at Rensselaer Polytechnic Institute propose a new theory - based on a richer, more accurate image of magnetic fields and solar winds in the early solar system, and a mechanism known as multi-fluid magneto-hydrodynamics - to explain the ancient heating of the asteroid belt.
Although today the asteroid belt between Mars and Jupiter is cold and dry, scientists have long known that warm, wet conditions, suitable to formation of some life-seeding biomolecules, prevailed.
One theory of the origin of life proposes that some of the biomolecules that formed on asteroids may have reached the surfaces of planets, and contributed to the origin of life.
"The early Sun was actually dimmer than the Sun today, so in terms of sunlight, the asteroid belt would have been even colder than it is now. And yet we know that some asteroids were heated to the temperature of liquid water, the 'goldilocks zone,' which enabled some of these interesting biomolecules to form," said researcher Wayne Roberge.
Both of the established theories - one involving the same radioactive process that heats the interior of Earth, and the other involving the interaction of plasma (super-heated gases that behave somewhat like fluids) and a magnetic field.
Roberge and Menzel reviewed the second theory, based on an early assessment of the young Sun and the premise that an object moving through a magnetic field will experience an electric field, which will in turn push electrical currents through the asteroid, heating the asteroid in the same way that electrical currents heat the wires in a toaster.
The solar wind, and the plasma stream it produced, was not as powerful as early theorists assumed, and the researchers have corrected those calculations based on the current understanding of the young Sun, researchers said.
Roberge said the early theorists also incorrectly calculated the position of the electric field asteroids would have experienced.
The study was published in The Astrophysical Journal.