Posted on 08/05/2018 9:48:03 AM PDT by Simon Green
A bizarre rogue planet without a star is roaming the Milky Way just 20 light-years from the Sun. And according to a recently published study in The Astrophysical Journal, this strange, nomadic world has an incredibly powerful magnetic field that is some 4 million times stronger than Earths. Furthermore, it generates spectacular auroras that would put our own northern lights to shame.
The new observations, made with the National Science Foundations Karl G. Jansky Very Large Array (VLA), not only are the first radio observations of a planetary-mass object beyond our solar system, but also mark the first time researchers have measured the magnetic field of such a body.
Sizing up SIMP
The peculiar and untethered object, succinctly named SIMP J01365663+0933473 (well call it SIMP for simplicity's sake), was first discovered back in 2016. At the time, researchers thought SIMP was a brown dwarf: an object thats too big to be a planet, but too small to be a star. However, last year, another study showed that SIMP is just small enough, at 12.7 times the mass and 1.2 times the radius of Jupiter, to be considered a planet albeit a mammoth one.
This object is right at the boundary between a planet and a brown dwarf, or failed star, and is giving us some surprises that can potentially help us understand magnetic processes on both stars and planets, said Arizona State Universitys Melodie Kao, who led the new study on SIMP, in a press release.
For a planet, SIMP is also pretty hot: The world has a surface temperature of over 1,500 degrees Fahrenheit (825 Celsius). For comparison, the hottest planet in our solar system is Venus, which sports an average temperature of around 875 F (470 C), while the Sun, a relatively small and cool star, has a surface temperature of about 10,000 F (5,500 C). However, its important to note that Venus gets most of its heat from the Sun. And since solitary SIMP is not orbiting a star, its heat must be leftover from its initial formation some 200 million years ago. So, over time, the planetary goliath will continue to radiate away its warmth.
That, together with the laws of probability applied to our best understanding of the formation of star systems like our own, indicates the spaces between the stars must be populated with a wide variety of planets and 'failed stars' and their offspring. Not enough to present a bigger challenge to interstellar travel than the speed of light or the human lifespan, but still a bigger challenge than a grain of sand.
It follows that our rudimentary efforts at detection would encounter the largest, more dynamic examples.
"The galaxy is huge, with many things, but few so rare as..."
There is also one other possible explanation
Note: this topic is from . Thanks Simon Green. Odd that I never pinged the Catastrophism list before this.
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