A self-lensing binary star system is one in which the mass of the closer star can be measured by how powerfully it magnifies light from its more distant companion star.
Working with University of Washington astronomer Eric Agol, doctoral student Ethan Kruse confirmed an astronomer's prediction in 1973, based on stellar evolution models of the time, that such a system should be possible.
Like so many interesting discoveries, this one happened largely by accident, researchers said.
Using data from the planet-hunting Kepler Space Telescope, Kruse saw something in the binary star system KOI-3278 that didn't make sense.
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"What you normally expect is this dip in brightness, but what you see in this system is basically the exact opposite - it looks like an anti-transit," said Kruse.
The two stars of KOI-3278, about 2,600 light-years away in the Lyra constellation, take turns being nearer to Earth as they orbit each other every 88.18 days.
They are about 43 million miles apart, roughly the distance the planet Mercury is from the Sun. The white dwarf, a cooling star thought to be in the final stage of life, is about Earth's size but 200,000 times more massive.
"The basic idea is fairly simple. Gravity warps space and time and as light travels toward us it actually gets bent, changes direction. So, any gravitational object - anything with mass - acts as a magnifying glass," Agol said.
"You really need large distances for it to be effective." said Agol.
"The cool thing, in this case, is that the lensing effect is so strong, we are able to use that to measure the mass of the closer, white dwarf star," said Agol.
Lensing within the Milky Way galaxy, such as this, is called microlensing.