Sentences with phrase «general relativity predicts»
Einstein's famous theory of general relativity predicts the existence of gravitational waves, but it's taken humanity over a century to develop the technological know - how to build a detector sensitive enough to perceive them.
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General relativity predicts that the black hole's shadow should be circular (middle), but a black hole could potentially also have a prolate (left) or oblate (right) shadow.
General relativity predicts that two massive objects in a tight orbit around each other will spiral in, slowly at first and then faster until they merge, distorting space - time in perturbations that ripple in all directions.
Einstein's Theory of General Relativity predicts that light coming from a strong gravitational field gets stretched out, or «redshifted.»
Albert Einstein's theory of general relativity predicts that clocks at different gravitational potentials will tick at different rates — a clock at higher elevation will tick faster than will a clock closer to Earth's center.
General relativity predicts these ripples in space - time, but so far no one has observed them directly.
As general relativity predicts, light from the background star bent around the white dwarf, distorted by its gravitational field.
Einstein's theory of general relativity predicts that the motion of slightly lopsided or asymmetrical objects should trigger gravitational waves in space.
Einstein's general relativity predicts that gravity from matter in the other universe would leak into ours.
As general relativity predicts, space sags around the mass of the lens galaxy, making light from the source bend on its way to us.
General relativity predicts that ripples in space - time should constantly be passing through Earth.
In a sense, general relativity predicts its own demise.
Scientists hope to spot a ringlike shadow around the black hole's boundary that general relativity predicts will occur as the hole's strong gravity deflects light.
However, Einstein's 1915 theory of general relativity predicted that such deflection could in fact occur — a prediction subsequently borne out by experiment.
(That actually proved a lucky break for Einstein, since his early version of general relativity predicted the wrong amount of deflection.)
Not exact matches
Using ultraprecise atomic clocks, scientists proved that for every one foot higher you move above the Earth's surface, time speeds up by a factor of 0.00000000000000004 due to the slight decrease in the force of gravity — just as general relativity would predict.
It was not until the detection of quasars, which allow astronomers to see the light emitted by matter falling into black holes, that we had evidence that they were real objects and not just mathematical curiosities predicted by Einstein's general theory of relativity.
In preparation for this search, physicists honed their general relativity skills on simulations of the spacetime storm kicked up by black holes, predicting what LIGO might see and building up the computational machinery to solve the equations of general relativity.
Those waves, predicted by Einstein's general theory of relativity, stretched and compressed spacetime, traveling outward like ripples on a pond.
General relativity alters the predicted amount of rotation, which explains why Mercury's orbit didn't quite align with earlier predictions.
Gravitational waves are predicted by Einstein's general theory of relativity but have so far never been detected.
Likewise, debate raged into the 1970s about whether general relativity really predicted gravity waves and, if so, whether the waves actually carried energy.
Few experts would predict that general relativity would make the wrong prediction.
Scientists have essentially been waiting for this day for a century, since Albert Einstein predicted gravitational waves in 1916 on the basis of his general theory of relativity.
The first confirmation that the theory of general relativity was correct came when Einstein proved it could be used it to accurately predict Mercury's orbit.
Einstein's general theory of relativity predicts that colliding black holes should produce the most thunderous gravity waves.
These characteristics would explain the extreme time dilation on the world where the film's intrepid planet hunters landed: In one hour there, seven elapsed on Earth, a phenomenon predicted by Einstein's general theory of relativity.
For if this discovery holds up to scrutiny — and some of my colleagues aren't sure that it does — it is the first direct sighting of the gravitational waves that Albert Einstein predicted shortly after he proposed his general theory of relativity in 1915.
Einstein's general theory of relativity predicts that gravitational waves — ripples in spacetime — emanate from accelerating massive objects.
Gravitational waves were first predicted 100 years ago by Albert Einstein as part of his Theory of General Relativity.
Their paths shift slightly from one orbit to the next — a phenomenon known as precession — but when astronomers use general relativity to predict the amount of this shift, their answers are off by a factor of four.
Albert Einstein first predicted gravitational waves in 1916 based on his general theory of relativity, but even he waffled about whether or not they truly exist.
The speed and pace of those measurements promise to add an increment of precision to GPS navigation, and ROMY may even be able to detect a subtle effect predicted by Albert Einstein's theory of general relativity: the drag of the rotating planet on nearby spacetime, like a spoon turned in a pot of honey.
Minute tremors in space itself, predicted by Einstein's general theory of relativity, are generated when massive objects accelerate.
Albert Einstein's general theory of relativity predicts that black hole mergers should send out intense blasts of gravitational waves, ripples in space - time.
Over the past decade or so our theoretical understanding of general relativity has improved a great deal, allowing us to calculate the precise pattern of gravitational waves it predicts for such a merger.
It will also verify if general relativity can accurately predict the magnitude of the effect.
Einstein@home What it is: So far none of the gravitational waves that Albert Einstein predicted in his theory of general relativity have been detected.
This quantum gravity theory would take over from general relativity in the extraordinarily tight quarters — the very core of a black hole, the very instant of the Big Bang — where relativity now predicts, absurdly, that space - time is infinitely curved.
IN ITS MODERN FORM, the concept of black holes emerges from Einstein's general theory of relativity, which predicts that if matter is sufficiently compressed, its gravity becomes so strong that it carves out a region of space from which nothing can escape.
Gravitational waves, the undulations produced in space - time when massive objects move, had long been predicted by Einstein's theory of general relativity.
With only one tight pair known, he says, it was difficult to assess how common even tighter black hole pairs are, which are crucial in the hunt for gravitational waves — a subtle type of radiation predicted by Einstein's general theory of relativity.
Two stars are speeding around the big black hole at the Milky Way's core in just the way his general theory of relativity predicted.
Physicists have sought to detect ripples in spacetime called gravitational waves ever since they realized Albert Einstein's general theory of relativity predicted their existence.
Gravitational waves, which have never been detected directly, were predicted by Albert Einstein in 1916 on the basis of his theory of general relativity, although he thought they were too weak to be observed, says Einstein@Home Director Bruce Allen, a physicist at Max Planck and U.W. — Milwaukee.
The gravitational Faraday effect, first predicted in the 1950s, theorizes that when linearly polarized light travels close to a spinning black hole, the orientation of its polarization rotates according to Einstein's theory of general relativity.
Albert Einstein's general theory of relativity predicts that a black hole's intense gravity bends passing rays of light.
A Florida State University high - performance computing researcher has predicted a physical effect that would help physicists and astronomers provide fresh evidence of the correctness of Einstein's general theory of relativity.
General relativity's no - hair theorem predicts an almost perfectly circular shadow; modifications to general relativity in which black holes retain their hair could yield an ellipsoidGeneral relativity's no - hair theorem predicts an almost perfectly circular shadow; modifications to general relativity in which black holes retain their hair could yield an ellipsoidgeneral relativity in which black holes retain their hair could yield an ellipsoidal one.
Wormholes, tunnels through the fabric of spacetime that connect widely separated locations, are predicted by Einstein's general theory of relativity.