Astronomers just used bizarre physics to predict the violent death of a star
Their prophecy is based on something strange glimpsed by the Hubble Space Telescope back in 2014, when the same astronomers saw four supernovas blowing up at once.
In reality, only one star blew up, but all the light coming from the supernova was magnified and distorted by a bizarre phenomenon called gravitational lensing.
Albert Einstein was the first to describe gravitational lensing, and though he couldn't believe it at the time, it predicts that massive objects with intense gravitational pull - like a planet, galaxy, or galaxy cluster - can dramatically bend and warp the fabric of space itself:
The gravitational field acts like a lens, bending and redirecting light from background objects. So, depending on your vantage point, smaller objects behind the big gravity field can appear huge or even in multiple places at once.
Which is exactly what happened with a cluster of galaxies called MACS J1149+2223.
The galaxy cluster is about 5 billion light-years away and, last year, acted as a gigantic lens for a supernova behind it. The supernova appeared in four different spots marked by arrows in the image below - a phenomenon called an "Einstein cross."
You might notice that all four images don't look the same; that's because the light is bent more in some images than others. The more the light is bent, the longer it takes to reach our telescopes:
Since astronomers first noticed it in November 2014, the supernova has faded away. But now they're predicting light from the same explosion will replay at a different spot within the same gravitational lens.
Their calculations, published in a study on the preprint server arXiv, suggest we'll see the supernova again sometime between January 2016 and April 2016.
This is a "once-in-a-lifetime" opportunity, according to a Hubble press release, to see how well we understand gravity lenses and other advanced physics.
It may also be the first time ever we'll get to zero in on and watch a star blow up from start to finish. That's huge, since supernovas make all of the atomic elements essential for life, yet we know very little about them.
[h/t @coreyspowell]