Gravitational Wave: Does Vibrating Mass Emit Waves?

  • Thread starter Ahmed Abdullah
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In summary, vibrating charges emit electromagnetic waves and according to theory, any vibrating mass is capable of producing gravitational waves. However, these gravitational waves have not yet been observed experimentally. Current experiments are using interferometers pointed at supernovae to detect spacetime distortions caused by gravitational waves, but this is a difficult task due to the weak nature of the gravitational force. Gravitational waves are only detectable from the strongest gravitational fields, such as those produced by closely orbiting pulsars and colliding neutron stars/black holes. While none have been detected yet, the sensitivity of LIGO is approaching the point where a detection is possible and the future launch of LISA holds great potential for this new branch of astronomy.
  • #1
Ahmed Abdullah
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Vibrating charges emits electromagnetic waves. Does any vibrating mass is capable of producing wave (that can be called graviational wave)?
 
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  • #2
Theory says, yes... it has not yet been observed experimentally.
 
  • #3
There are experiments going on at the moment - pointing michelson-morley style interferometers at supernovae and trying to detect the spacetime distortions (supposedly) given off. Because the gravitational force is actually incredibly weak, these are very difficult to see - hence the supernova-as-a-subject requirement; nothing else is powerful enough.
 
  • #4
Gravitational waves are incredibly weak (OOM 10-40 em waves) and might be detectable but only from the strongest gravitational fields.

Note that if the system retains spherical symmetry, such as in a Cepheid Variable star that oscillates in diameter, or a supernova that explodes more or less symmetrically, gravitational waves are not produced.

Systems that should produce detectable gravitational waves are closely orbiting pulsars PSR J0737-3039A/B and colliding neutron stars/black holes such as those that are thought to be a possible source of short GRBs. As Integral said none have yet been detected.

Garth
 
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  • #6
This is quite an exciting field: If astronomical source estimates are correct, LIGO is now approaching the sensitivity where there is a real chance of them making a detection anytime in the next "year or several" -- and whenever LISA launches, it should be swamped with signal (interferometers work like omnidirectional microphones). With any luck there will exist a completely new branch of astronomy within a couple decades.
 

1. What are gravitational waves?

Gravitational waves are ripples in the fabric of spacetime caused by the acceleration of massive objects. They were first predicted by Albert Einstein in his theory of general relativity.

2. How are gravitational waves created?

Gravitational waves are created when massive objects, such as black holes or neutron stars, accelerate or change direction. This causes ripples in the fabric of spacetime, which propagate outwards at the speed of light.

3. Can we detect gravitational waves?

Yes, gravitational waves have been detected by several experiments, including the Laser Interferometer Gravitational-Wave Observatory (LIGO) and the Virgo interferometer. These experiments use lasers to measure tiny changes in the distance between two points caused by passing gravitational waves.

4. How do gravitational waves differ from electromagnetic waves?

Gravitational waves are fundamentally different from electromagnetic waves. While electromagnetic waves are caused by the oscillation of electric and magnetic fields, gravitational waves are caused by the curvature of spacetime. Additionally, electromagnetic waves can travel through a vacuum, while gravitational waves require a medium (spacetime) to propagate.

5. Can we use gravitational waves for communication?

No, gravitational waves cannot be used for communication as they are extremely weak and difficult to detect. Additionally, they do not carry information in the same way as electromagnetic waves do. However, the detection of gravitational waves has opened up a new window for studying the universe and has the potential to reveal new insights about the nature of gravity and the cosmos.

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