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Credit & Copyright: LIGO, Caltech,
NSF
Explanation:
Accelerate a charge and you'll get
electromagnetic radiation: light.
But accelerate any mass and you'll get
gravitational radiation.
Light is seen all the time, but, so far,
a confirmed direct detection of
gravitational radiation has
yet to be made.
When absorbed,
gravitational waves (GWs) create a
tiny symmetric jiggle similar to squashing a
rubber ball and letting go quickly.
Separated detectors can be used to discern
GWs from everyday bumps.
Powerful astronomical GW sources would coincidentally
jiggle even detectors on opposite ends of the Earth.
Pictured above are the two-kilometer-long arms
of one such detector: the
LIGO Hanford Observatory in
Washington,
which recently achieved a
phase-lock milestone to future GW detection.
When it and its
sister interferometer in
Louisiana
come online in 2002, they may see a
GW sky so
strange it won't be immediately understood.
APOD mourns the recent passing of
Joseph Weber, a visionary thinker and pioneer in
gravitational wave detection.
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NASA Web Site Statements, Warnings, and Disclaimers
NASA Official: Jay Norris. Specific rights apply.
A service of: LHEA at NASA / GSFC
& Michigan Tech. U.
Based on Astronomy Picture
Of the Day
Publications with keywords: gravitational radiation - LIGO
Publications with words: gravitational radiation - LIGO
See also:
- Simulation: Two Black Holes Merge
- APOD: 2023 June 29 Á A Message from the Gravitational Universe
- Ninety Gravitational Wave Spectrograms and Counting
- GW200115: Simulation of a Black Hole Merging with a Neutron Star
- When Black Holes Collide
- Fifty Gravitational Wave Events Illustrated
- GW190521: Unexpected Black Holes Collide