October’s Night Sky Notes: Let’s Go, LIGO!

September 2025 marks the 10th anniversary of the first direct detection of gravitational waves by LIGO, a milestone that confirms Albert Einstein’s 1916 theory of General Relativity.
Gravitational waves are ripples in space-time created by massive objects accelerating in space, such as black holes merging or stars going supernova. These invisible waves can be detected using laser interferometers like LIGO.
LIGO works by splitting a laser beam into two and sending it down each of its 2.5-mile-long arms, which are arranged in an “L” shape. When the beams return, any slight stretching or squeezing caused by a gravitational wave creates a measurable shift in the interference pattern.
Since LIGO’s detection, there have been over 300 black hole mergers detected, with two additional observatories (VIRGO and KAGRA) contributing to this total. The public can help with projects like Black Hole Hunters and Gravity Spy to aid in gravitational wave research.
Gravitational waves are not directly detectable by humans, but their presence can be inferred through the tiny changes they cause in space-time. By studying these effects, scientists can gain insights into the universe’s most violent events and the behavior of black holes.

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October’s Night Sky Notes: Let’s Go, LIGO!

An artist’s impression of gravitational waves generated by binary neutron stars.

Credits:
R. Hurt/Caltech-JPL

by Kat Troche of the Astronomical Society of the Pacific

September 2025 marks ten years since the first direct detection of gravitational waves as predicted by Albert Einstein’s 1916 theory of General Relativity. These invisible ripples in space were first directly detected by the Laser Interferometer Gravitational-Wave Observatory (LIGO). Traveling at the speed of light (~186,000 miles per second), these waves stretch and squeeze the fabric of space itself, changing the distance between objects as they pass.

Waves In Space

Gravitational waves are created when massive objects accelerate in space, especially in violent events. LIGO detected the first gravitational waves when two black holes, orbiting one another, finally merged, creating ripples in space-time. But these waves are not exclusive to black holes. If a star were to go supernova, it could produce the same effect. Neutron stars can also create these waves for various reasons. While these waves are invisible to the human eye, this animation from NASA’s Science Visualization Studio shows the merger of two black holes and the waves they create in the process.

Two black dots circle each other at the center of this animation. Gravitational waves are represented stylistically by spirals that begin as purple, trialing right behind each black hole and then swirling around as they expand off the edge of the screen. The black holes get closer and closer, while the spirals get denser and more frequent until the two black holes merge. As soon as they merge, the new spirals stop, while the existing ones expand away from the single black dot at the center. In the end there is just a single black hole on a black background with a grid, representing space-time.

Two black holes orbit each other, generating space-time ripples called gravitational waves in this animation. As the black holes get closer, the waves increase in until they merge completely.

NASA’s Goddard Space Flight Center Conceptual Image Lab

How It Works

A gravitational wave observatory, like LIGO, is built with two tunnels, each approximately 2.5 miles long, arranged in an “L” shape. At the end of each tunnel, a highly polished 40 kg mirror (about 16 inches across) is mounted; this will reflect the laser beam that is sent from the observatory. A laser beam is sent from the observatory room and split into two, with equal parts traveling down each tunnel, bouncing off the mirrors at the end. When the beams return, they are recombined. If the arm lengths are perfectly equal, the light waves cancel out in just the right way, producing darkness at the detector. But if a gravitational wave passes, it slightly stretches one arm while squeezing the other, so the returning beams no longer cancel perfectly, creating a flicker of light that reveals the wave’s presence.

Animation of gravitational waves being detected.

When a gravitational wave passes by Earth, it squeezes and stretches space. LIGO can detect this squeezing and stretching. Each LIGO observatory has two “arms” that are each more than 2 miles (4 kilometers) long. A passing gravitational wave causes the length of the arms to change slightly. The observatory uses lasers, mirrors, and extremely sensitive instruments to detect these tiny changes.

NASA

The actual detection happens at the point of recombination, when even a minuscule stretching of one arm and squeezing of the other changes how long it takes the laser beams to return. This difference produces a measurable shift in the interference pattern. To be certain that the signal is real and not local noise, both LIGO observatories — one in Washington State (LIGO Hanford) and the other in Louisiana (LIGO Livingston) — must record the same pattern within milliseconds. When they do, it’s confirmation of a gravitational wave rippling through Earth. We don’t feel these waves as they pass through our planet, but we now have a method of detecting them!

Get Involved

With the help of two additional gravitational-wave observatories, VIRGO and KAGRA, there have been 300 black hole mergers detected in the past decade; some of which are confirmed, while others await further study.

While the average person may not have a laser interferometer lying around in the backyard, you can help with two projects geared toward detecting gravitational waves and the black holes that contribute to them:

Black Hole Hunters: Using data from the TESS satellite, you would study graphs of how the brightness of stars changes over time, looking for an effect called gravitational microlensing. This lensing effect can indicate that a massive object has passed in front of a star, such as a black hole.
Gravity Spy: You can help LIGO scientists with their gravitational wave research by looking for glitches that may mimic gravitational waves. By sorting out the mimics, we can train algorithms on how to detect the real thing.

You can also use gelatin, magnetic marbles, and a small mirror for a more hands-on demonstration on how gravitational waves move through space-time with JPL’s Dropping In With Gravitational Waves activity!

link

Q. What is the speed at which gravitational waves travel?

A. Gravitational waves travel at the speed of light, approximately 186,000 miles per second.

Q. How do gravitational waves affect space-time?

A. Gravitational waves stretch and squeeze the fabric of space itself, changing the distance between objects as they pass.

Q. What type of event creates gravitational waves?

A. Massive objects accelerating in space, especially in violent events such as black hole mergers or supernovae explosions.

Q. How do LIGO observatories detect gravitational waves?

A. LIGO uses lasers, mirrors, and extremely sensitive instruments to detect the tiny changes caused by a passing gravitational wave, which causes a measurable shift in the interference pattern.

Q. What is the purpose of having two “arms” in each LIGO observatory?

A. The two arms are used to create an “L” shape, allowing for the detection of gravitational waves by measuring the difference in time it takes for laser beams to return from each arm.

Q. How do scientists confirm that a detected signal is real and not local noise?

A. Both LIGO observatories must record the same pattern within milliseconds to confirm that the signal is real.

Q. What are some ways to get involved with gravitational wave research?

A. One can participate in projects such as Black Hole Hunters, Gravity Spy, or use gelatin, magnetic marbles, and a small mirror for a hands-on demonstration on how gravitational waves move through space-time.

Q. How many black hole mergers have been detected by LIGO and its partners since 2015?

A. Over 300 black hole mergers have been detected in the past decade, with some awaiting further study.

Q. What is gravitational microlensing?

A. Gravitational microlensing is an effect that can indicate the presence of a massive object, such as a black hole, passing in front of a star.

Q. How do scientists train algorithms to detect gravitational waves?

A. By sorting out mimics of gravitational waves, which helps to improve the detection capabilities of LIGO and other observatories.