Albert Einstein's
general theory of relativity predicts that a black hole's intense gravity bends passing rays of light.
Albert Einstein's
general theory of relativity predicts that black hole mergers should send out intense blasts of gravitational waves, ripples in space - time.
Einstein's
general theory of relativity predicts that gravitational waves — ripples in spacetime — emanate from accelerating massive objects.
Einstein's
general theory of relativity predicts that colliding black holes should produce the most thunderous gravity waves.
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.
Einstein's 1915
general theory of relativity predicted that events, like two black holes colliding, should distort the fabric of spacetime with gravitational waves.
Not exact matches
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.
Those waves,
predicted by Einstein's
general theory of relativity, stretched and compressed spacetime, traveling outward like ripples on a pond.
Gravitational waves are
predicted by Einstein's
general theory of relativity but have so far never been detected.
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.
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.
However, Einstein's 1915
theory of general relativity predicted that such deflection could in fact occur — a prediction subsequently borne out by experiment.
Gravitational waves were first
predicted 100 years ago by Albert Einstein as part
of his
Theory of General Relativity.
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.
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.
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.
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.
Einstein's
theory of general relativity predicts that the motion
of slightly lopsided or asymmetrical objects should trigger gravitational waves in space.
Wormholes, tunnels through the fabric
of spacetime that connect widely separated locations, are
predicted by Einstein's
general theory of relativity.
First
predicted by Einstein more than a century ago as a consequence
of his
theory of general relativity, gravitational waves were long thought to be beyond observational reach — if not entirely nonexistent.
This effect, which is
predicted by the
theory of general relativity, has been detected in the light from stars, and observed in experiments on Earth.
First, it would tell us that gravitational waves,
predicted by Einstein's century - old
theory of general relativity, really do exist.
An international team
of astronomers has found the most distant gravitational lens yet — a galaxy that, as
predicted by Albert Einstein's
general theory of relativity, deflects and intensifies the light
of an even more distant object.
Predicted by Einstein's
general theory of relativity, wormholes are tunnels connecting two points in space - time.
Black holes, which were
predicted by Einstein's
theory of general relativity, have an event horizon — a boundary beyond which nothing, even light, can return to the outside world.
The waves are
predicted by Einstein's
general theory of relativity.
To complicate matters, the
theory of special
relativity, which preceded
general relativity by a decade,
predicts a similar effect for clocks in motion — a stationary clock will tick faster than a moving clock.
General relativity scored a knockout blow when Einstein
predicted the motion
of Mercury with greater accuracy than Newton's
theory of gravity could.
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.
Einstein's
Theory of General Relativity predicts that light coming from a strong gravitational field gets stretched out, or «redshifted.»
And the amazing thing is that the amount
of lensing that we found through these calculations is consistent with what Einstein's
general relativity theory predicted.
Nearly 50 years ago, Rainer Weiss dreamed up a way to detect gravitational waves — infinitesimal ripples in spacetime
predicted by Einstein's
theory of gravity,
general relativity.
Such models also suffer from being nonrelativistic — they can not describe the bending
of light by gravity, an effect
predicted so well by a relativistic
theory of gravity such as Einstein's
general theory of relativity.
Gravitational waves — ripples in the fabric
of space and time produced by dramatic events in the universe, such as merging black holes, and
predicted as a consequence
of Albert Einstein's 1915
general theory of relativity — carry information about their origins and about the nature
of gravity that can not otherwise be obtained.
Caption: Light rays from a distant galaxy are deflected due to the gravity
of a massive, foreground galaxy, as
predicted by Einstein's
theory of general relativity.
The Laser Interferometer Gravitational - Wave Observatory (LIGO) is designed to open the field
of gravitational - wave astrophysics through the direct detection
of gravitational waves
predicted by Einstein's
general theory of relativity.
Microlensing relies upon measurements
of the gravitational bending
of light (
predicted by Albert Einstein's
general theory of relativity) from a more distant source by an intervening star and its planets.
Gravitational waves were
predicted by Albert Einstein in 1915 as part
of his
theory of general relativity, but it wasn't until last year that it was confirmed we had directly detected these waves.
Researchers with the Laser Interferometer Gravitational - Wave Observatory (LIGO) announced today (Feb. 11) that they had made history's first direct detection
of gravitational waves, enigmatic ripples in space - time whose existence was first
predicted 100 years ago by Albert Einstein's famous
theory of general relativity.
Einstein Rings Albert Einstein's
General Theory of Relativity, published in 1916,
predicted that massive objects, such as stars, could bend light rays passing nearby.