Q&A

Can we generate gravity waves?

Can we generate gravity waves?

Every massive object that accelerates produces gravitational waves. This includes humans, cars, airplanes etc., but the masses and accelerations of objects on Earth are far too small to make gravitational waves big enough to detect with our instruments.

Do planets emit gravitational waves?

Now researchers suggest the first extragalactic planets may get detected not via light signals, but gravitational-wave signals. When two or more objects move within a gravitational field, they produce gravitational waves that travel at the speed of light, stretching and squeezing space-time along the way.

Does sun emit gravitational waves?

Even the Earth–sun system radiates gravitational waves, but just how powerful are they? Someone asked me recently why it’s only black holes and compact objects like neutron stars that produce gravitational waves. The answer is that it isn’t only these objects.

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What generates gravitational waves?

Gravitational waves are ‘ripples’ in space-time caused by some of the most violent and energetic processes in the Universe. The strongest gravitational waves are produced by cataclysmic events such as colliding black holes, supernovae (massive stars exploding at the end of their lifetimes), and colliding neutron stars.

Are gravitational waves faster than light?

A gravitational wave is an invisible (yet incredibly fast) ripple in space. Gravitational waves travel at the speed of light (186,000 miles per second). A gravitational wave is an invisible (yet incredibly fast) ripple in space. We’ve known about gravitational waves for a long time.

How many gravitational waves has LIGO detected?

50 detections
As of December 2019, LIGO has made 3 runs, and made 50 detections of gravitational waves. Maintenance and upgrades of the detectors are made between runs. The first run, O1, which ran from 12 September 2015 to 19 January 2016, made the first 3 detections, all black hole mergers.

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Did Einstein believe in gravitational waves?

Einstein soon hit on the correct formulation, but two decades later he rejected the physical reality of gravitational waves, and he remained skeptical about them for the rest of his life. Like most scientific concepts, that of gravitational waves emerged over many years, through the work of numerous architects.

Why is LIGO so precise?

Since we know that the longer the arms of an interferometer, the more sensitive the instrument is to vibration, this design significantly increases LIGO’s sensitivity and enables it to detect changes in arm length much smaller than a proton–the size of changes expected to be caused by a gravitational wave.

What is a gravitational wave?

A gravitational wave is an invisible (yet incredibly fast) ripple in space. Gravitational waves travel at the speed of light (186,000 miles per second).

What are the ripples of space gravitational waves?

Scientists call these ripples of space gravitational waves. Gravitational waves are invisible. However, they are incredibly fast. They travel at the speed of light (186,000 miles per second). Gravitational waves squeeze and stretch anything in their path as they pass by.

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What types of gravitational waves have LIGO detected so far?

So far, all of the objects LIGO has detected fall into this category. Compact binary inspiral gravitational waves are produced by orbiting pairs of massive and dense (“compact”) objects like white dwarf stars, black holes, and neutron stars. There are three subclasses of “compact binary” systems in this category of gravitational-wave generators:

Why is it so hard to detect gravitational waves?

Credit: LIGO/T. Pyle But these types of objects that create gravitational waves are far away. And sometimes, these events only cause small, weak gravitational waves. The waves are then very weak by the time they reach Earth. This makes gravitational waves hard to detect. How do we know that gravitational waves exist?