gravitational variometer - significado y definición. Qué es gravitational variometer
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Qué (quién) es gravitational variometer - definición

TYPE OF ASTRONOMY INVOLVING OBSERVATION OF GRAVITATIONAL WAVES
Graviton astronomy; Gravitational wave astronomy; Detection of gravitational waves; Gravitational wave detection; Gravitational-wave detection; Gravitational-wave observation; Gravitational wave observation; Gravitational waves detection; Gravitational-Wave Astronomy
  • supernova]], represented by the explosion in the third panel.

Gravitational lens         
  • Eddington]]'s photographs of the 1919 [[solar eclipse]] experiment, presented in his 1920 paper announcing its success
  • Gravitational lensing – intervening galaxy modifies appearance of a galaxy far behind it (video; artist's concept).
  • access-date=23 June 2017}}</ref>
  • This schematic image shows how light from a distant galaxy is distorted by the gravitational effects of a foreground galaxy, which acts like a lens and makes the distant source appear distorted, but magnified, forming characteristic rings of light, known as Einstein rings.
  • An analysis of the distortion of SDP.81 caused by this effect has revealed star-forming clumps of matter.
  • access-date=29 October 2018}}</ref>
  • A light source passes behind a gravitational lens (invisible point mass placed in the center of the image). The aqua circle is the light source as it would be seen if there were no lens, while white spots are the multiple images of the source (see [[Einstein ring]]).
  • This image from the NASA/ESA Hubble Space Telescope shows the galaxy cluster [[MACS J1206]].
DISTRIBUTION OF MATTER BETWEEN A DISTANT LIGHT SOURCE AND A OBSERVER
Gravitational lensing; Gravitational lense; Gravitational Lens; Bend light; Gravitationally lensed galaxy; Gravitational arc; Einstein arc; Gravitational Lensing; Gravity lens; Gravitational lenses; Multiple images (gravitational lensing); Gravitatinal lensing; Gravitational Lenses; Macrolensing; Solar lens; Gravitational deflection
A gravitational lens is a distribution of matter (such as a cluster of galaxies) between a distant light source and an observer that is capable of bending the light from the source as the light travels toward the observer. This effect is known as gravitational lensing, and the amount of bending is one of the predictions of Albert Einstein's general theory of relativity.
gravitational lens         
  • Eddington]]'s photographs of the 1919 [[solar eclipse]] experiment, presented in his 1920 paper announcing its success
  • Gravitational lensing – intervening galaxy modifies appearance of a galaxy far behind it (video; artist's concept).
  • access-date=23 June 2017}}</ref>
  • This schematic image shows how light from a distant galaxy is distorted by the gravitational effects of a foreground galaxy, which acts like a lens and makes the distant source appear distorted, but magnified, forming characteristic rings of light, known as Einstein rings.
  • An analysis of the distortion of SDP.81 caused by this effect has revealed star-forming clumps of matter.
  • access-date=29 October 2018}}</ref>
  • A light source passes behind a gravitational lens (invisible point mass placed in the center of the image). The aqua circle is the light source as it would be seen if there were no lens, while white spots are the multiple images of the source (see [[Einstein ring]]).
  • This image from the NASA/ESA Hubble Space Telescope shows the galaxy cluster [[MACS J1206]].
DISTRIBUTION OF MATTER BETWEEN A DISTANT LIGHT SOURCE AND A OBSERVER
Gravitational lensing; Gravitational lense; Gravitational Lens; Bend light; Gravitationally lensed galaxy; Gravitational arc; Einstein arc; Gravitational Lensing; Gravity lens; Gravitational lenses; Multiple images (gravitational lensing); Gravitatinal lensing; Gravitational Lenses; Macrolensing; Solar lens; Gravitational deflection
¦ noun Astronomy a massive object whose gravitational field distorts light passing through it, producing a multiple image of a more remote object.
Gravitational wave         
  • access-date=18 October 2017}}</ref>
  • The effect of a cross-polarized gravitational wave on a ring of particles
  • The effect of a plus-polarized gravitational wave on a ring of particles
  • access-date=17 March 2014}}</ref>
  • LIGO measurement of the gravitational waves at the Hanford (left) and Livingston (right) detectors, compared to the theoretical predicted values.
  • A schematic diagram of a laser interferometer
  • doi = 10.1038/nature.2015.16830}}</ref>
  • Linearly polarised gravitational wave
  • access-date=20 September 2016}}</ref>
PROPAGATING SPACETIME RIPPLE
Gravitational waves; Existence of gravitational waves; Gravitational Radiation; Gravitational Wave; Gravitational radiation; Gravitational wave radiation; High Frequency Gravitational Waves; Gravitational Waves; High-Frequency Gravitational Waves; Gravity wave detector; Gravitation wave; Gravity of waves; Gravitational of waves; Gravitation waves; Gravitationl waves; Gravitational damping; Persistent gravitational wave observables; PGWO
Gravitational waves are disturbances or ripples in the curvature of spacetime, generated by accelerated masses, that propagate as waves outward from their source at the speed of light. They were first proposed by Oliver Heaviside in 1893 and then later by Henri Poincaré in 1905http://www.

Wikipedia

Gravitational-wave astronomy

Gravitational-wave astronomy is an emerging branch of observational astronomy which aims to use gravitational waves (minute distortions of spacetime predicted by Albert Einstein's theory of general relativity) to collect observational data about objects such as neutron stars and black holes, events such as supernovae, and processes including those of the early universe shortly after the Big Bang.

Gravitational waves have a solid theoretical basis, founded upon the theory of relativity. They were first predicted by Einstein in 1916; although a specific consequence of general relativity, they are a common feature of all theories of gravity that obey special relativity. However, after 1916 there was a long debate whether the waves were actually physical, or artefacts of coordinate freedom in general relativity; this was not fully resolved until the 1950s. Indirect observational evidence for their existence first came in the late 1980s, from the monitoring of the Hulse–Taylor binary pulsar (discovered 1974); the pulsar orbit was found to evolve exactly as would be expected for gravitational wave emission. Hulse and Taylor were awarded the 1993 Nobel Prize in Physics for this discovery.

On 11 February 2016 it was announced that the LIGO collaboration had directly observed gravitational waves for the first time in September 2015. The second observation of gravitational waves was made on 26 December 2015 and announced on 15 June 2016. Barry Barish, Kip Thorne and Rainer Weiss were awarded the 2017 Nobel Prize in Physics for leading this work.