Our solar system is hurtling through space while angled nearly perpendicular to the plane of the Milky Way, new computer models suggest.
"It's almost like we're sailing through the galaxy sideways," said study team leader Merav Opher, an astrophysicist at George Mason University in Virginia.
The findings, detailed in the May 11 issue of the journal Science, suggest the magnetic field in the galactic environment surrounding our solar system is pitched at a sharp angle and not oriented parallel to the plane of the Milky Way as previously thought.
The clue to the angle was found in the charged cocoon-like shroud around the solar system, called the heliosphere and comprised of the sun's solar wind, the stream of charged, low-energy particles it emits. As our sun and its planets travel through space, interstellar gases press against the heliosphere, stretching this steady cosmic gale lengthwise into a bullet shape that stretches far past Pluto.
Data recently received from the Voyager 1 and 2 spacecraft reveal the heliosphere's shape is deformed in another way: the northern hemisphere bulges outward while the southern hemisphere is pressed inward.
The galactic magnetic field influences the orientation of the solar system's heliosphere, causing it to incline at a sharp angle, Opher said. An analogy is a bullet hurtling through the air with its nose turned toward the ground.
"If you assume that you have a magnetic field in the plane of the galaxy, you get the wrong distortion," Opher told SPACE.com.
The new study is the first to look at the local galactic magnetic field, Opher said. Previous research involved measuring the galactic field over massive distances, more than a thousand times the scale of the heliosphere.
Slideshow: Month in Space: January 2014 "It's like instead of measuring continents, you're measuring countries," Opher said.
The source of our galaxy's magnetic field is a mystery. The most accepted idea, Opher said, is that the large cloud of interstellar dust and gas from which our galaxy formed had a magnetic field, and that the field got squished when the cloud collapsed into a disk to form the Milky Way.
"But you can also ask 'What formed the magnetic field of this cloud?'" Opher said.
Randy Jokipii, an astrophysicist at the University of Arizona who was not involved in the new study, suggests in an accompanying Science article that the findings of Opher's team can be explained if the galactic magnetic field is thought of as a turbulent fluid. Turbulence is a phenomenon whereby a fluid breaks down randomly into eddies and no longer flows smoothly, like creamer poured into a cup of coffee.
Opher says the idea of a turbulent galactic magnetic field is not new to scientists. "We've thought about it, but [our findings] indicate it might really exist," she said.
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