Earth images from space: 10 incredible photos of our planet

NASA’s Lunar Orbiter 1 took the first Earth image as seen from the vicinity of the moon in 1966. Forty-two years later, NASA released this much higher resolution version reprocessed from the original analog data tapes. Image via Wikimedia. See more Earth images from space below.

To celebrate Earth Day today, enjoy these incredible Earth images from space.

Originally published by NASA Science; the author is Phil Davis

It suddenly struck me that that tiny pea, pretty and blue, was the Earth. I put up my thumb and shut one eye, and my thumb blotted out the planet Earth. I didn’t feel like a giant. I felt very, very small.

– Neil Armstrong, Apollo 11

1. Voyager 1: At 7.2 million miles … and 4 billion miles

Voyager 1’s image of Earth and the moon, September 18, 1977. Image via NASA/ JPL.

The famous pale blue dot from Voyager 1 on February 14, 1990. Image via NASA/ JPL.

Voyager famously captured two unique views of our home world from afar. The upper image, taken in 1977 from a distance of 7.3 million miles (11.7 million km), showed the full Earth and full moon in a single frame for the first time in history.

The second image, taken in 1990 as part of a family portrait of our solar system from 4 billion miles (6.4 billion km), shows Earth as a tiny blue speck in a ray of sunlight. This is the famous “Pale Blue Dot” image immortalized by Carl Sagan.

Sagan’s widow, Ann Druyan, said of the image:

This was our willingness to see the Earth as a 1-pixel object in a far greater cosmos. It’s that humility that science gives us. That weans us from our childhood need to be the center of things. And Voyager gave us that image of the Earth that is so heart tugging because you can’t look at that image and not think of how fragile, how fragile our world is. How much we have in common with everyone with whom we share it; our relationship, our relatedness, to everyone on this tiny pixel.

2. Kepler: A bright flashlight in a dark sea of stars

Kepler’s view of Earth from December 10, 2017. Image via NASA/ Ames Research Center.

NASA’s Kepler mission captured Earth’s image as it slipped past at a distance of 94 million miles (151 million km). The reflection was so extraordinarily bright that it created a saber-like saturation bleed across the instrument’s sensors, obscuring the neighboring moon.

3. Cassini: Hello and goodbye

Right, Cassini’s view in 2013. Left, a final look between the rings in 2017. Image via NASA.

This beautiful shot of Earth as a dot beneath Saturn’s rings was taken in 2013 as thousands of humans on Earth waved at the exact moment the Cassini spacecraft pointed its cameras at our home world. Then, in 2017, Cassini caught this final view of Earth between Saturn’s rings as the spacecraft spiraled in for its Grand Finale at Saturn.

4. Lunar Reconnaissance Orbiter: “Simply stunning”

NASA’s Lunar Reconnaissance Orbiter (LRO) captured a unique view of Earth from the spacecraft’s vantage point in orbit around the moon on October 12, 2015. Image via NASA/ Goddard/ Arizona State University.

The image is simply stunning. The image of the Earth evokes the famous Blue Marble image taken by astronaut Harrison Schmitt during Apollo 17 … which also showed Africa prominently in the picture.

– Noah Petro, Deputy Project Scientist for NASA’s Lunar Reconnaissance Orbiter mission.

5. OSIRIS-REx: Goodbye – for now – at 19,000 mph

NASA’s OSIRIS-REx spacecraft captured this image of the Earth and moon. Image via NASA.

As part of an engineering test, NASA’s OSIRIS-REx spacecraft captured this image of Earth and the moon in January 2018 from a distance of 39.5 million miles (63.6 million km). When the camera acquired the image, the spacecraft was moving away from our home planet at a speed of 19,000 miles per hour (8.5 km per second). Earth is the largest, brightest spot in the center of the image, with the smaller, dimmer moon appearing to the right. Several constellations are also visible in the surrounding space.

6. Curiosity: The view from Mars

This view of the twilight sky and Martian horizon taken by NASA’s Mars Curiosity rover includes Earth as the brightest point of light in the night sky. Image via NASA/ JPL-Caltech/ MSSS/ TAMU.

A human observer with normal vision, standing on Mars, could easily see Earth and the moon as two distinct, bright “evening stars.”

7. DSCOVR: Moon photobombs Earth

Earth and moon from a million miles out. Image via NASA/ NOAA.

This image from the Deep Space Climate Observatory (DSCOVR) satellite captured a unique view of the moon as it moved in front of the sunlit side of Earth in 2015. It provides a view of the far side of the moon, which is never directly visible to us here on Earth. I found this perspective profoundly moving and only through our satellite views could this have been shared.

– Michael Freilich, Director of NASA’s Earth Science Division

8. Galileo: 8 days out

The Galileo spacecraft’s view as it departed Earth. Image via NASA.

Eight days after its final encounter with Earth – the second of two gravitational assists from Earth that helped boost the spacecraft to Jupiter – the Galileo spacecraft looked back and captured this remarkable view of our planet and its moon. The image was taken from a distance of about 3.9 million miles (6.2 million km).

9. Rosetta: A slice of life

Rosetta’s view of Earth. Image via ESA ©2009 MPS for OSIRIS Team MPS/ UPD/ LAM/ IAA/ RSSD/ INTA/ UPM/ DASP/ IDA.

Earth from about 393,000 miles (633,000 km) away, as seen by the European Space Agency’s comet-bound Rosetta spacecraft during its 3rd and final swing-by of our home planet in 2009.

10. MESSENGER: So long

MESSENGER’s view departing Earth. Image via NASA/ JHUAPL/ Carnegie Institution of Washington.

The Mercury-bound MESSENGER spacecraft captured several stunning images of Earth during a gravity assist swing-by of its home planet on August 2, 2005.

Bottom line: Ten amazing images of Earth from space.

The post Earth images from space: 10 incredible photos of our planet first appeared on EarthSky.

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NASA’s Lunar Orbiter 1 took the first Earth image as seen from the vicinity of the moon in 1966. Forty-two years later, NASA released this much higher resolution version reprocessed from the original analog data tapes. Image via Wikimedia. See more Earth images from space below.

To celebrate Earth Day today, enjoy these incredible Earth images from space.

Originally published by NASA Science; the author is Phil Davis

It suddenly struck me that that tiny pea, pretty and blue, was the Earth. I put up my thumb and shut one eye, and my thumb blotted out the planet Earth. I didn’t feel like a giant. I felt very, very small.

– Neil Armstrong, Apollo 11

1. Voyager 1: At 7.2 million miles … and 4 billion miles

Voyager 1’s image of Earth and the moon, September 18, 1977. Image via NASA/ JPL.

The famous pale blue dot from Voyager 1 on February 14, 1990. Image via NASA/ JPL.

Voyager famously captured two unique views of our home world from afar. The upper image, taken in 1977 from a distance of 7.3 million miles (11.7 million km), showed the full Earth and full moon in a single frame for the first time in history.

The second image, taken in 1990 as part of a family portrait of our solar system from 4 billion miles (6.4 billion km), shows Earth as a tiny blue speck in a ray of sunlight. This is the famous “Pale Blue Dot” image immortalized by Carl Sagan.

Sagan’s widow, Ann Druyan, said of the image:

This was our willingness to see the Earth as a 1-pixel object in a far greater cosmos. It’s that humility that science gives us. That weans us from our childhood need to be the center of things. And Voyager gave us that image of the Earth that is so heart tugging because you can’t look at that image and not think of how fragile, how fragile our world is. How much we have in common with everyone with whom we share it; our relationship, our relatedness, to everyone on this tiny pixel.

2. Kepler: A bright flashlight in a dark sea of stars

Kepler’s view of Earth from December 10, 2017. Image via NASA/ Ames Research Center.

NASA’s Kepler mission captured Earth’s image as it slipped past at a distance of 94 million miles (151 million km). The reflection was so extraordinarily bright that it created a saber-like saturation bleed across the instrument’s sensors, obscuring the neighboring moon.

3. Cassini: Hello and goodbye

Right, Cassini’s view in 2013. Left, a final look between the rings in 2017. Image via NASA.

This beautiful shot of Earth as a dot beneath Saturn’s rings was taken in 2013 as thousands of humans on Earth waved at the exact moment the Cassini spacecraft pointed its cameras at our home world. Then, in 2017, Cassini caught this final view of Earth between Saturn’s rings as the spacecraft spiraled in for its Grand Finale at Saturn.

4. Lunar Reconnaissance Orbiter: “Simply stunning”

NASA’s Lunar Reconnaissance Orbiter (LRO) captured a unique view of Earth from the spacecraft’s vantage point in orbit around the moon on October 12, 2015. Image via NASA/ Goddard/ Arizona State University.

The image is simply stunning. The image of the Earth evokes the famous Blue Marble image taken by astronaut Harrison Schmitt during Apollo 17 … which also showed Africa prominently in the picture.

– Noah Petro, Deputy Project Scientist for NASA’s Lunar Reconnaissance Orbiter mission.

5. OSIRIS-REx: Goodbye – for now – at 19,000 mph

NASA’s OSIRIS-REx spacecraft captured this image of the Earth and moon. Image via NASA.

As part of an engineering test, NASA’s OSIRIS-REx spacecraft captured this image of Earth and the moon in January 2018 from a distance of 39.5 million miles (63.6 million km). When the camera acquired the image, the spacecraft was moving away from our home planet at a speed of 19,000 miles per hour (8.5 km per second). Earth is the largest, brightest spot in the center of the image, with the smaller, dimmer moon appearing to the right. Several constellations are also visible in the surrounding space.

6. Curiosity: The view from Mars

This view of the twilight sky and Martian horizon taken by NASA’s Mars Curiosity rover includes Earth as the brightest point of light in the night sky. Image via NASA/ JPL-Caltech/ MSSS/ TAMU.

A human observer with normal vision, standing on Mars, could easily see Earth and the moon as two distinct, bright “evening stars.”

7. DSCOVR: Moon photobombs Earth

Earth and moon from a million miles out. Image via NASA/ NOAA.

This image from the Deep Space Climate Observatory (DSCOVR) satellite captured a unique view of the moon as it moved in front of the sunlit side of Earth in 2015. It provides a view of the far side of the moon, which is never directly visible to us here on Earth. I found this perspective profoundly moving and only through our satellite views could this have been shared.

– Michael Freilich, Director of NASA’s Earth Science Division

8. Galileo: 8 days out

The Galileo spacecraft’s view as it departed Earth. Image via NASA.

Eight days after its final encounter with Earth – the second of two gravitational assists from Earth that helped boost the spacecraft to Jupiter – the Galileo spacecraft looked back and captured this remarkable view of our planet and its moon. The image was taken from a distance of about 3.9 million miles (6.2 million km).

9. Rosetta: A slice of life

Rosetta’s view of Earth. Image via ESA ©2009 MPS for OSIRIS Team MPS/ UPD/ LAM/ IAA/ RSSD/ INTA/ UPM/ DASP/ IDA.

Earth from about 393,000 miles (633,000 km) away, as seen by the European Space Agency’s comet-bound Rosetta spacecraft during its 3rd and final swing-by of our home planet in 2009.

10. MESSENGER: So long

MESSENGER’s view departing Earth. Image via NASA/ JHUAPL/ Carnegie Institution of Washington.

The Mercury-bound MESSENGER spacecraft captured several stunning images of Earth during a gravity assist swing-by of its home planet on August 2, 2005.

Bottom line: Ten amazing images of Earth from space.

The post Earth images from space: 10 incredible photos of our planet first appeared on EarthSky.

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A pileus cloud means bad weather is on the way

View at EarthSky Community Photos. | Amrinderjit Singh in Vaatalya, Himachal Pradesh, India, captured this pileus cloud on April 18, 2026. A pileus cloud is a curved cap on top of a towering cumulus cloud. Amrinderjit wrote: “Pileus clouds are formed by strong updrafts (small-scale currents of rising air) within the cloud at lower altitudes. They are short-lived clouds and indicate severe weather ahead.” Thank you, Amrinderjit!

A pileus cloud is a sign of bad weather

Have you ever seen a bubbling, towering cloud wearing a curved white cap on its head? These cap clouds – or pileus clouds – are a sign of bad weather. They form above vigorously growing cumulus or cumulonimbus clouds. If you see one, be prepared for storms.

Cumulus clouds are serene, fluffy clouds. When most people are asked to draw a cloud, a cumulus cloud is the kind they will sketch. Cumulus clouds can start as fair-weather clouds, but if conditions are right they can become cumulonimbus clouds, or thunderheads. In a moist, unstable atmosphere, updrafts can cause cumulus clouds to grow, blossoming into the giant cauliflower shapes of cumulonimbus. Their bases grow dark as they grow thicker, because sunlight cannot penetrate them.

As these towering clouds push higher and higher into the atmosphere, they can bump into a stable layer of humid air. As the cloud continues to billow upward, it lifts that humid air above its dew point. The dew point is the temperature the air must cool to in order to become saturated with water vapor. At this point, the air cannot hold more moisture, so it condenses into clouds, resulting in the curved cloud cap on top of the thunderhead.

If you see one, snap a pic, because they won’t last long! The rising air continues its upward motion, mixing the air and merging the cap with the growing cloud.

More pics of pileus clouds

View at EarthSky Community Photos. | Helio C. Vital in Saquarem, Rio de Janeiro, Brazil, captured this unusually thick pileus cloud on February 13, 2024. Helio wrote: “The pileus cloud formed as air quickly rose inside a cumulus cloud and condensed at its top, yielding a smooth umbrella shape. It lasted for some 5 minutes and then suddenly collapsed, swallowed by the mother cloud.” Thank you, Helio!

View at EarthSky Community Photos. | Peter Lowenstein in Mutare, Zimbabwe, captured this iridescent pileus cloud on January 8, 2020. Peter wrote: “Uprising moisture condensed on top of some cumulus clouds to form tiny ice crystals, which refracted sunlight to produce characteristic shining pileus caps. These only persisted for a few minutes, with early ones remaining colorless and later ones developing rainbow colors as the sun descended in the sky.” Thank you, Peter!

Bottom line: A pileus cloud looks like a curved, white cap on the top of a towering cumulus cloud. Pileus clouds are a sign that bad weather is on the way.

Read more: Cloud shapes are a useful tool for predicting weather

The post A pileus cloud means bad weather is on the way first appeared on EarthSky.

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View at EarthSky Community Photos. | Amrinderjit Singh in Vaatalya, Himachal Pradesh, India, captured this pileus cloud on April 18, 2026. A pileus cloud is a curved cap on top of a towering cumulus cloud. Amrinderjit wrote: “Pileus clouds are formed by strong updrafts (small-scale currents of rising air) within the cloud at lower altitudes. They are short-lived clouds and indicate severe weather ahead.” Thank you, Amrinderjit!

A pileus cloud is a sign of bad weather

Have you ever seen a bubbling, towering cloud wearing a curved white cap on its head? These cap clouds – or pileus clouds – are a sign of bad weather. They form above vigorously growing cumulus or cumulonimbus clouds. If you see one, be prepared for storms.

Cumulus clouds are serene, fluffy clouds. When most people are asked to draw a cloud, a cumulus cloud is the kind they will sketch. Cumulus clouds can start as fair-weather clouds, but if conditions are right they can become cumulonimbus clouds, or thunderheads. In a moist, unstable atmosphere, updrafts can cause cumulus clouds to grow, blossoming into the giant cauliflower shapes of cumulonimbus. Their bases grow dark as they grow thicker, because sunlight cannot penetrate them.

As these towering clouds push higher and higher into the atmosphere, they can bump into a stable layer of humid air. As the cloud continues to billow upward, it lifts that humid air above its dew point. The dew point is the temperature the air must cool to in order to become saturated with water vapor. At this point, the air cannot hold more moisture, so it condenses into clouds, resulting in the curved cloud cap on top of the thunderhead.

If you see one, snap a pic, because they won’t last long! The rising air continues its upward motion, mixing the air and merging the cap with the growing cloud.

More pics of pileus clouds

View at EarthSky Community Photos. | Helio C. Vital in Saquarem, Rio de Janeiro, Brazil, captured this unusually thick pileus cloud on February 13, 2024. Helio wrote: “The pileus cloud formed as air quickly rose inside a cumulus cloud and condensed at its top, yielding a smooth umbrella shape. It lasted for some 5 minutes and then suddenly collapsed, swallowed by the mother cloud.” Thank you, Helio!

View at EarthSky Community Photos. | Peter Lowenstein in Mutare, Zimbabwe, captured this iridescent pileus cloud on January 8, 2020. Peter wrote: “Uprising moisture condensed on top of some cumulus clouds to form tiny ice crystals, which refracted sunlight to produce characteristic shining pileus caps. These only persisted for a few minutes, with early ones remaining colorless and later ones developing rainbow colors as the sun descended in the sky.” Thank you, Peter!

Bottom line: A pileus cloud looks like a curved, white cap on the top of a towering cumulus cloud. Pileus clouds are a sign that bad weather is on the way.

Read more: Cloud shapes are a useful tool for predicting weather

The post A pileus cloud means bad weather is on the way first appeared on EarthSky.

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Meet M13, the Great Globular Cluster in Hercules

View at EarthSky Community Photos. | Gwen Forrester in DeKalb County, Tennessee, captured this telescopic view of Messier 13 (M13), the Great Hercules Cluster, on May 23, 2025. Thank you, Gwen!

The Great Cluster in the constellation Hercules – also known as Messier 13, or M13 – is the finest globular cluster in the northern half of the heavens. More specifically, you can find it in a star pattern called the Keystone, a lopsided square within the constellation Hercules. This constellation is located between the two brightest stars of northern spring and summer, Vega and Arcturus.

Under constant observation

From mid-northern latitudes, the M13 cluster is in the sky for at least part of the night all year round. As you read this, someone, somewhere, is observing M13. It’s rising a few hours after sunset in April. Then, it’s above the horizon all night long in May, June and July. In August, September and October, the Hercules Cluster is still very much a night owl, staying up till after midnight. Then, in November and December, you can see it in your western evening sky and in your eastern morning sky. It is in the morning sky from January through April.

Moreover, when you gaze at M13 or other globular star clusters, you are looking at stars that are some 12 to 13 billion years old. That’s almost as old as the universe.

M13 is easy to find

The constellation Hercules is where you’ll find M13. Hercules is between summertime’s two brightest stars, Vega in Lyra the Harp and Arcturus in Boötes the Herdsman.

About 1/3 of the way from Vega to Arcturus, locate the four modestly bright stars forming the squarish Keystone of Hercules. On the Arcturus side of the Keystone, M13 lies between the stars Eta Herculis and Zeta Herculis.

A typical binocular field is about 5 to 7 degrees in diameter, and the Hercules cluster is found about 2.5 degrees south of Eta Herculis.

The Hercules cluster’s position is Right Ascension: 16h 41.7m; Declination: 36 degrees 28′ north.

The bright star Vega in the constellation Lyra the Harp and the orange star Arcturus in the constellation Boötes the Herdsman are located on either side of the constellation Hercules. Then look for the squarish pattern within Hercules. This pattern is called the Keystone. M13 is located along one of the borders of the Keystone.

What to expect from M13

On a dark, clear night, the unaided eye barely perceives the Hercules cluster as a faint and fuzzy point of light. Indeed, this fuzzy “star” is much easier to make out in binoculars. The cluster shines at magnitude 5.8 and is about 20 arcminutes in size, about 2/3 the diameter of the full moon.

The best way to see M13 – or any globular cluster – is through telescopes with large apertures (light-gathering capability). Smaller telescopes will show this globular cluster, but they will not resolve the cluster into individual stars. However, if you don’t have a telescope, or are unfamiliar with how to use one, try attending a public star party. That way you can view M13 through an assortment of telescopes.

Sky chart of the constellation Hercules, showing the whereabouts of Messier 13, the Hercules cluster. Image via IAU/ Sky and Telescope/ Wikimedia Commons (CC BY 3.0).

What’s that propeller doing in this cluster?

Now that we have M13 in our telescope, let’s look for an oddity unique to this globular cluster. Look for what appears to be three dark lanes that form the shape of an airplane propeller. Bindon Blood Stoney, assistant to the Earl of Rosse in the 1850s, was the first to notice this odd feature. It is a pattern caused by the lack of stars along this particular line of sight.

M13 and the propeller. Here, north is up, east is to the left. Image via Phil Harrington, from his book: Cosmic Challenge. Used with permission.

Walter Scott Houston, who wrote a monthly column called “Deep-Sky Wonders” for Sky and Telescope magazine, mentioned M13’s propeller in 1953. From time to time he would mention it again; still, none of his readers reported ever seeing it. Finally, in 1980, American amateur astronomer John Bortle wrote that he saw it, and it is located on the southeast corner of the cluster. Aperture and magnification help in seeing it, because a large telescope and at least 200 magnification is necessary to bring it out from the background. Most photographs overexpose the area, and therefore the propeller disappears.

Counting stars

M13 is very far away, 25,000 light-years. This is several times farther away than the farthest stars you can see with the unaided eye. And the cluster is large, about 165 light-years across.

Overall, how many stars does M13 have? About 300,000, and perhaps as many as a half million. In fact, that is about 100 times more than the number of stars you can see with your eyes alone in our sky at night.

View at EarthSky Community Photos. | Tameem Altameemi in the United Arab Emirates shared this image on April 26, 2025, and wrote: “This image features the beautiful globular cluster Messier 13. In the same field of view, the spiral galaxy NGC 6207 and the faint active galaxy IC 4617 are visible.” Thank you, Tameem!

Talking to a globular cluster

On November 16, 1974, the Arecibo radio telescope in Puerto Rico sent a radio message to M13. This was the first message deliberately sent toward a target in outer space. Designed by a team led by Frank Drake, the message communicated information about our world. Read more about the message here. It will take 25,000 years for the message to reach the cluster. Correspondingly, any response will take another 25,000 years to reach us.

View at EarthSky Community Photos. | Tom Cofer in Lakewood Ranch, Florida, captured this telescopic view of Messier 13 or M13, the Great Globular Cluster in Hercules, on March 14, 2025. Tom wrote: “A snow globe of stars!” Thank you, Tom!

Two types of clusters

M13 is a globular star cluster, a huge globe-shaped stellar city teeming with hundreds of thousands of stars. Globular clusters orbit the Milky Way Galaxy outside the galactic disk at tens of thousands of light-years away. In contrast, the relatively nearby Pleiades and Hyades are open star clusters that reside within the galactic disk. In general, they usually harbor a few hundred to a thousand stars.

The discovery of M13

Englishman Edmond Halley discovered this cluster in 1714 “by help of the telescope.” He stated:

This is but a little patch, but it shows itself to the [unaided] eye when the sky is serene and the moon absent.

On June 1, 1764, the famous French comet hunter Charles Messier (1730-1817) listed this object as number 13 in his catalog of nebulous objects. He described it as:

… A nebula which I am sure contains no star. Round and brilliant, center brighter than the edges.

Messier’s telescope, however, was not powerful enough to show the individual stars.

In the centuries since then, M13 has become the most observed globular cluster in the Northern Hemisphere.

View larger. | The heart of M13, aka the Great Cluster in Hercules, a globular star cluster and one of our Milky Way Galaxy’s oldest inhabitants. Image via the Advanced Camera for Surveys on the Hubble Space Telescope.

Bottom line: Meet M13, the Great Cluster, in Hercules. Peering at this globular cluster is a wonderful way to start your spring or summer evening.

Hercules is between 2 bright stars: Vega and Arcturus

The Pleiades – or 7 Sisters – known around the world

The Hyades star cluster: The Face of Taurus the Bull

The post Meet M13, the Great Globular Cluster in Hercules first appeared on EarthSky.

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View at EarthSky Community Photos. | Gwen Forrester in DeKalb County, Tennessee, captured this telescopic view of Messier 13 (M13), the Great Hercules Cluster, on May 23, 2025. Thank you, Gwen!

The Great Cluster in the constellation Hercules – also known as Messier 13, or M13 – is the finest globular cluster in the northern half of the heavens. More specifically, you can find it in a star pattern called the Keystone, a lopsided square within the constellation Hercules. This constellation is located between the two brightest stars of northern spring and summer, Vega and Arcturus.

Under constant observation

From mid-northern latitudes, the M13 cluster is in the sky for at least part of the night all year round. As you read this, someone, somewhere, is observing M13. It’s rising a few hours after sunset in April. Then, it’s above the horizon all night long in May, June and July. In August, September and October, the Hercules Cluster is still very much a night owl, staying up till after midnight. Then, in November and December, you can see it in your western evening sky and in your eastern morning sky. It is in the morning sky from January through April.

Moreover, when you gaze at M13 or other globular star clusters, you are looking at stars that are some 12 to 13 billion years old. That’s almost as old as the universe.

M13 is easy to find

The constellation Hercules is where you’ll find M13. Hercules is between summertime’s two brightest stars, Vega in Lyra the Harp and Arcturus in Boötes the Herdsman.

About 1/3 of the way from Vega to Arcturus, locate the four modestly bright stars forming the squarish Keystone of Hercules. On the Arcturus side of the Keystone, M13 lies between the stars Eta Herculis and Zeta Herculis.

A typical binocular field is about 5 to 7 degrees in diameter, and the Hercules cluster is found about 2.5 degrees south of Eta Herculis.

The Hercules cluster’s position is Right Ascension: 16h 41.7m; Declination: 36 degrees 28′ north.

The bright star Vega in the constellation Lyra the Harp and the orange star Arcturus in the constellation Boötes the Herdsman are located on either side of the constellation Hercules. Then look for the squarish pattern within Hercules. This pattern is called the Keystone. M13 is located along one of the borders of the Keystone.

What to expect from M13

On a dark, clear night, the unaided eye barely perceives the Hercules cluster as a faint and fuzzy point of light. Indeed, this fuzzy “star” is much easier to make out in binoculars. The cluster shines at magnitude 5.8 and is about 20 arcminutes in size, about 2/3 the diameter of the full moon.

The best way to see M13 – or any globular cluster – is through telescopes with large apertures (light-gathering capability). Smaller telescopes will show this globular cluster, but they will not resolve the cluster into individual stars. However, if you don’t have a telescope, or are unfamiliar with how to use one, try attending a public star party. That way you can view M13 through an assortment of telescopes.

Sky chart of the constellation Hercules, showing the whereabouts of Messier 13, the Hercules cluster. Image via IAU/ Sky and Telescope/ Wikimedia Commons (CC BY 3.0).

What’s that propeller doing in this cluster?

Now that we have M13 in our telescope, let’s look for an oddity unique to this globular cluster. Look for what appears to be three dark lanes that form the shape of an airplane propeller. Bindon Blood Stoney, assistant to the Earl of Rosse in the 1850s, was the first to notice this odd feature. It is a pattern caused by the lack of stars along this particular line of sight.

M13 and the propeller. Here, north is up, east is to the left. Image via Phil Harrington, from his book: Cosmic Challenge. Used with permission.

Walter Scott Houston, who wrote a monthly column called “Deep-Sky Wonders” for Sky and Telescope magazine, mentioned M13’s propeller in 1953. From time to time he would mention it again; still, none of his readers reported ever seeing it. Finally, in 1980, American amateur astronomer John Bortle wrote that he saw it, and it is located on the southeast corner of the cluster. Aperture and magnification help in seeing it, because a large telescope and at least 200 magnification is necessary to bring it out from the background. Most photographs overexpose the area, and therefore the propeller disappears.

Counting stars

M13 is very far away, 25,000 light-years. This is several times farther away than the farthest stars you can see with the unaided eye. And the cluster is large, about 165 light-years across.

Overall, how many stars does M13 have? About 300,000, and perhaps as many as a half million. In fact, that is about 100 times more than the number of stars you can see with your eyes alone in our sky at night.

View at EarthSky Community Photos. | Tameem Altameemi in the United Arab Emirates shared this image on April 26, 2025, and wrote: “This image features the beautiful globular cluster Messier 13. In the same field of view, the spiral galaxy NGC 6207 and the faint active galaxy IC 4617 are visible.” Thank you, Tameem!

Talking to a globular cluster

On November 16, 1974, the Arecibo radio telescope in Puerto Rico sent a radio message to M13. This was the first message deliberately sent toward a target in outer space. Designed by a team led by Frank Drake, the message communicated information about our world. Read more about the message here. It will take 25,000 years for the message to reach the cluster. Correspondingly, any response will take another 25,000 years to reach us.

View at EarthSky Community Photos. | Tom Cofer in Lakewood Ranch, Florida, captured this telescopic view of Messier 13 or M13, the Great Globular Cluster in Hercules, on March 14, 2025. Tom wrote: “A snow globe of stars!” Thank you, Tom!

Two types of clusters

M13 is a globular star cluster, a huge globe-shaped stellar city teeming with hundreds of thousands of stars. Globular clusters orbit the Milky Way Galaxy outside the galactic disk at tens of thousands of light-years away. In contrast, the relatively nearby Pleiades and Hyades are open star clusters that reside within the galactic disk. In general, they usually harbor a few hundred to a thousand stars.

The discovery of M13

Englishman Edmond Halley discovered this cluster in 1714 “by help of the telescope.” He stated:

This is but a little patch, but it shows itself to the [unaided] eye when the sky is serene and the moon absent.

On June 1, 1764, the famous French comet hunter Charles Messier (1730-1817) listed this object as number 13 in his catalog of nebulous objects. He described it as:

… A nebula which I am sure contains no star. Round and brilliant, center brighter than the edges.

Messier’s telescope, however, was not powerful enough to show the individual stars.

In the centuries since then, M13 has become the most observed globular cluster in the Northern Hemisphere.

View larger. | The heart of M13, aka the Great Cluster in Hercules, a globular star cluster and one of our Milky Way Galaxy’s oldest inhabitants. Image via the Advanced Camera for Surveys on the Hubble Space Telescope.

Bottom line: Meet M13, the Great Cluster, in Hercules. Peering at this globular cluster is a wonderful way to start your spring or summer evening.

Hercules is between 2 bright stars: Vega and Arcturus

The Pleiades – or 7 Sisters – known around the world

The Hyades star cluster: The Face of Taurus the Bull

The post Meet M13, the Great Globular Cluster in Hercules first appeared on EarthSky.

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Small ants clean larger ants in a surprising twist of nature

Small cone ants clean a much larger harvester ant. Scientists said this behavior marks the first known case of interspecies ant grooming. Image via Mark Moffett/ Minden Pictures (used with permission).

Small ants clean larger ants

Scientists have discovered a unique interaction between two ant species: smaller ants cleaning much larger ones. It’s the first known case of this behavior in insects, said entomologist Mark Moffett of the Smithsonian National Museum of Natural History on April 13, 2026.

Moffett observed and documented this phenomenon while studying ant behavior in the Chiricahua Mountains of southeastern Arizona. During his research, he noticed that harvester ants actively seek out cone ants and allow them to groom their bodies.

Moffet published his discovery on April 12, 2026, in the peer-reviewed journal Ecology and Evolution.

1st known case of interspecies ant grooming

The behavior begins when a harvester ant leaves its nest and approaches a cone ant colony. Instead of showing aggression or defensive behavior, the large ant stops abruptly, often standing still with its mandibles open and its body held high.

Within seconds, cone ants emerge from the nest and climb onto the harvester ant’s body. They move quickly across its surface, using their mouthparts to lick and scrape tiny particles from its exoskeleton. The cleaning is deliberate and methodical, covering the head, legs and even sensitive areas near the mandibles.

These interactions vary widely in duration. Some last less than 15 seconds, while others continue for several minutes. In more intense encounters, multiple cone ants work simultaneously on a single harvester ant, creating a coordinated cleaning session. Remarkably, even when cone ants enter the open jaws of the larger ant, no aggression occurs. Moffett said:

The potentially dangerous harvester ants even permit the visitors to groom between their open jaws.

Once the interaction ends, the harvester ant suddenly jerks its body and dislodges the smaller ants with force before resuming its normal activities.

Here’s a harvester ant on a nest, waiting for cone ants to arrive. Image via Mark Moffett/ Minden Pictures (used with permission).

Why do small ants clean larger ants?

Scientists are still working to understand the evolutionary logic behind this unusual relationship. But early evidence suggests both species may gain specific benefits from the interaction.

Cone ants appear to consume microscopic particles found on the surface of harvester ants. These particles may include fragments of seed material or organic debris collected during foraging. Interestingly, cone ants only engage in this behavior with living harvester ants and completely ignore dead individuals placed near their nests. This suggests the interaction depends on chemical cues or movement from the host ant.

For harvester ants, the benefit may lie in improved hygiene. While they already perform mutual grooming within their own colonies, cone ants can access regions of the body that are difficult for nestmates to reach. This may help reduce parasites, fungal spores or bacterial buildup that could otherwise affect colony health. Moffett said:

Given the usual tendencies of ants, I first assumed that I was observing aggression. But the larger ants seemed to seek the attention of the smaller ants by first visiting their nests and then allowing the small ants to lick and nibble all over them.

Harvester ants collect seeds as part of their foraging routine, sometimes becoming hosts for smaller cone ants that feed on microscopic debris from their bodies. Image via Mark Moffett/ Minden Pictures/ Smithsonian.

A discovery that mirrors ocean life

This interaction strongly resembles cleaning systems found in marine environments, where small fish and shrimp remove parasites from much larger fish, including predators like sharks. Moffett commented:

This new ant species is the insect equivalent of cleaner fish in the ocean.

The similarity raises interesting questions about whether such cooperative behavior evolves independently in different environments. In both cases, a smaller species gains food while a larger species receives hygiene benefits.

Cone ant workers carefully clean harvester ants. Because they are smaller, they can reach places other nestmates can’t. Image via Mark Moffett/ Minden Pictures (used with permission).

There’s nothing to fear, as both species get benefits. Here’s a cone ant exploring between the mandibles of a harvester ant worker. Image via Mark Moffett/ Minden Pictures (used with permission).

What this means for insect research

Moffett emphasizes that this discovery highlights how much remains unknown about insect behavior in natural environments. He argues that field observation continues to play a crucial role in uncovering complex ecological relationships that laboratory studies might miss. Moffett said:

All kinds of amazing discoveries are still there to be made outside of the lab. Finding new species and behaviors in nature often requires us to pay close attention to the small things — including the ants.

He also notes that the behavior was easy to overlook at first, as it occurs quickly and in a remote desert environment. However, repeated observations confirmed that it was not accidental but a consistent pattern.

The finding opens new research directions, including whether similar interspecies grooming systems exist elsewhere and how widespread this type of cooperation might be among insects.

Cone ants get food from microscopic debris on harvester ants, while harvester ants gain external cleaning that may reduce parasites and improve hygiene. Here’s a harvester worker that has thrown herself onto her back to remove the cone ants that were cleaning her after an extended period of time. Team work! Image via Mark Moffett/ Minden Pictures (used with permission).

Bottom line: Small ants clean larger ants in the first known case of interspecies grooming between ants. A researcher spotted this rare behavior in Arizona.

Source: The First Cleaner Ant? A Novel Partnership in the Arizona Desert

Via Smithsonian

Read more: Queen ants found giving birth to 2 different species

Read more: Ants, little but tough: Lifeform of the week

The post Small ants clean larger ants in a surprising twist of nature first appeared on EarthSky.

from EarthSky https://ift.tt/ZcSioXk

Small cone ants clean a much larger harvester ant. Scientists said this behavior marks the first known case of interspecies ant grooming. Image via Mark Moffett/ Minden Pictures (used with permission).

Small ants clean larger ants

Scientists have discovered a unique interaction between two ant species: smaller ants cleaning much larger ones. It’s the first known case of this behavior in insects, said entomologist Mark Moffett of the Smithsonian National Museum of Natural History on April 13, 2026.

Moffett observed and documented this phenomenon while studying ant behavior in the Chiricahua Mountains of southeastern Arizona. During his research, he noticed that harvester ants actively seek out cone ants and allow them to groom their bodies.

Moffet published his discovery on April 12, 2026, in the peer-reviewed journal Ecology and Evolution.

1st known case of interspecies ant grooming

The behavior begins when a harvester ant leaves its nest and approaches a cone ant colony. Instead of showing aggression or defensive behavior, the large ant stops abruptly, often standing still with its mandibles open and its body held high.

Within seconds, cone ants emerge from the nest and climb onto the harvester ant’s body. They move quickly across its surface, using their mouthparts to lick and scrape tiny particles from its exoskeleton. The cleaning is deliberate and methodical, covering the head, legs and even sensitive areas near the mandibles.

These interactions vary widely in duration. Some last less than 15 seconds, while others continue for several minutes. In more intense encounters, multiple cone ants work simultaneously on a single harvester ant, creating a coordinated cleaning session. Remarkably, even when cone ants enter the open jaws of the larger ant, no aggression occurs. Moffett said:

The potentially dangerous harvester ants even permit the visitors to groom between their open jaws.

Once the interaction ends, the harvester ant suddenly jerks its body and dislodges the smaller ants with force before resuming its normal activities.

Here’s a harvester ant on a nest, waiting for cone ants to arrive. Image via Mark Moffett/ Minden Pictures (used with permission).

Why do small ants clean larger ants?

Scientists are still working to understand the evolutionary logic behind this unusual relationship. But early evidence suggests both species may gain specific benefits from the interaction.

Cone ants appear to consume microscopic particles found on the surface of harvester ants. These particles may include fragments of seed material or organic debris collected during foraging. Interestingly, cone ants only engage in this behavior with living harvester ants and completely ignore dead individuals placed near their nests. This suggests the interaction depends on chemical cues or movement from the host ant.

For harvester ants, the benefit may lie in improved hygiene. While they already perform mutual grooming within their own colonies, cone ants can access regions of the body that are difficult for nestmates to reach. This may help reduce parasites, fungal spores or bacterial buildup that could otherwise affect colony health. Moffett said:

Given the usual tendencies of ants, I first assumed that I was observing aggression. But the larger ants seemed to seek the attention of the smaller ants by first visiting their nests and then allowing the small ants to lick and nibble all over them.

Harvester ants collect seeds as part of their foraging routine, sometimes becoming hosts for smaller cone ants that feed on microscopic debris from their bodies. Image via Mark Moffett/ Minden Pictures/ Smithsonian.

A discovery that mirrors ocean life

This interaction strongly resembles cleaning systems found in marine environments, where small fish and shrimp remove parasites from much larger fish, including predators like sharks. Moffett commented:

This new ant species is the insect equivalent of cleaner fish in the ocean.

The similarity raises interesting questions about whether such cooperative behavior evolves independently in different environments. In both cases, a smaller species gains food while a larger species receives hygiene benefits.

Cone ant workers carefully clean harvester ants. Because they are smaller, they can reach places other nestmates can’t. Image via Mark Moffett/ Minden Pictures (used with permission).

There’s nothing to fear, as both species get benefits. Here’s a cone ant exploring between the mandibles of a harvester ant worker. Image via Mark Moffett/ Minden Pictures (used with permission).

What this means for insect research

Moffett emphasizes that this discovery highlights how much remains unknown about insect behavior in natural environments. He argues that field observation continues to play a crucial role in uncovering complex ecological relationships that laboratory studies might miss. Moffett said:

All kinds of amazing discoveries are still there to be made outside of the lab. Finding new species and behaviors in nature often requires us to pay close attention to the small things — including the ants.

He also notes that the behavior was easy to overlook at first, as it occurs quickly and in a remote desert environment. However, repeated observations confirmed that it was not accidental but a consistent pattern.

The finding opens new research directions, including whether similar interspecies grooming systems exist elsewhere and how widespread this type of cooperation might be among insects.

Cone ants get food from microscopic debris on harvester ants, while harvester ants gain external cleaning that may reduce parasites and improve hygiene. Here’s a harvester worker that has thrown herself onto her back to remove the cone ants that were cleaning her after an extended period of time. Team work! Image via Mark Moffett/ Minden Pictures (used with permission).

Bottom line: Small ants clean larger ants in the first known case of interspecies grooming between ants. A researcher spotted this rare behavior in Arizona.

Source: The First Cleaner Ant? A Novel Partnership in the Arizona Desert

Via Smithsonian

Read more: Queen ants found giving birth to 2 different species

Read more: Ants, little but tough: Lifeform of the week

The post Small ants clean larger ants in a surprising twist of nature first appeared on EarthSky.

from EarthSky https://ift.tt/ZcSioXk

Meteor showers are here! 10 easy tips for watching

You deserve a daily dose of good news. For the latest in science and the night sky, subscribe to EarthSky’s free daily newsletter.

Hooray! It’s meteor time! That’s right, the Lyrid meteor shower rambles across for a few weeks around April 22.

When is the next meteor shower? Click here for EarthSky’s meteor shower guide

So, how can you optimize your chances of seeing a great meteor display? Follow the tips below.

View at EarthSky Community Photos. | Jeremy Evans of California captured a Lyrid meteor zipping along the Milky Way on April 22, 2025. Jeremy wrote: “Lyrid meteor shower at peak activity. It was a quiet shower this year. I had my camera going all night and only caught one meteor. This single frame is from an all-night 1,200 frame time lapse on my front deck. I’m very fortunate to live under dark Bortle 2 skies. The glow on the horizon is from the last quarter moon just before rising. This meteor also left smoke trails.” Thank you, Jeremy.

1. Know the peak time

Generally, meteor showers happen over many days as Earth encounters a wide stream of icy particles in space. These particles are debris left behind by a comet. So the peak is a point in time when Earth is expected to encounter the greatest number of comet particles. To find the peak dates of meteor showers, check EarthSky’s meteor guide.

And here’s the catch … the peak of the shower comes at the same time for all of us on Earth. Meanwhile, our clocks are saying different times. You’ll often need to adjust from UTC to your local time.

However, the predictions are not always right on the money. And remember … it’s possible to see nice meteor displays in the hours – even days – before or after the predicted peak.

Also, keep in mind that meteor showers are part of nature. So naturally, they often defy prediction.

2. Location, location, location

We can’t say this strongly enough. It’s important to have a dark place to observe in the country. Visit EarthSky’s Best Places to Stargaze.

And … you need a wide-open view of the sky. A farmer’s field? Maybe a stretch of country road? Or a campsite with a clear view in one or more directions? That’s because an open sky will increase your chances of seeing some meteors.

3. Oh no! The moon is out

During a meteor shower, a bright moon is not your friend. In fact, nothing dampens the display of a meteor shower more effectively than a bright moon.

If the moon is out, look at areas of the sky away from the moon. Anything in the moon’s vicinity – including meteors – will likely be washed out by its bright light. And, another tip for watching in moonlight: place some object between yourself and the moon. Observing from the shadow of a barn, or vehicle, even a tree, can help you see more meteors. Basically, place yourself somewhere in the moon’s shadow.

4. Know the expected rate

Here, we touch on a topic that sometimes leads to some disappointment, especially among novice meteor-watchers: the rate.

Tables of meteor showers almost always list what is known as the zenithal hourly rate (ZHR) for each shower.

So the ZHR is the number of meteors you’ll see if you’re watching in a very dark sky, with the radiant overhead, when the shower is at its peak. In other words, the ZHR represents the number of meteors you might see per hour given the very best observing conditions during the shower’s maximum.

If the peak occurs when it’s still daylight at your location, if most of the meteors are predominantly faint, if a bright moon is out or if you’re located in a light-polluted area, the total number of meteors you see will be considerably reduced.

5. Don’t worry too much about radiant points

You don’t need to stare all night in a single direction – or even locate the radiant point – to have fun watching the shower. The meteors will appear all over the sky.

But … although you can see meteors shoot up from the horizon before a shower’s radiant rises, you’ll see more meteors after it rises. And you’ll see the most when the radiant is highest in the sky. So, find out the radiant point’s rising time. Then you can pinpoint the best time of night to watch the shower.

And … the radiant point is interesting. If you track meteors backward on the sky’s dome, you’ll find them streaming from their radiant point, a single point within a given constellation. Hence the meteor shower’s name.

6. Watch for an hour or more

Meteor showers will be better if you let your eyes adapt to the dark. That can take as long as 20 minutes. Plus, the meteors tend to come in spurts, followed by lulls. So, be patient! You’ll see some.

7. Notice the meteors’ speeds and colors

The Leonids are the swiftest meteors and the Taurids are the slowest meteors. The nice thing about a slow or medium speed meteor shower – such as the Lyrids – is if you see one and yell “meteor,” other people can catch it as well.

In fact, of the upcoming meteor showers … the Lyrids and the Delta Aquariids are medium speed showers. The Eta Aquariids and Perseids are swift meteors.

Plus, the April Lyrids, the December Geminids, and the August Perseids, can be colorful.

8. Watch for meteor trains

A meteor train is a persistent glow in the air left by some meteors after they have faded from view. Trains are from luminous ionized matter left in the wake of this incoming space debris. Some of the bright Lyrid meteors leave a persistent train. So you you might be lucky and see one.

9. Bring a blanket, a buddy, a hot drink and a lawn chair

A reclining lawn chair helps you lie back in comfort for an hour or more of meteor-watching.

If several of you are watching, take different parts of the sky. If you see one, shout “Meteor!” Dress warmly; the nights can be cool or cold, even during the summer months. You’ll probably appreciate that blanket and warm drink in the wee hours of the morning. Also, leave your laptops and tablets home; even using the nighttime dark mode will ruin your night vision. And this will be tough on some people: leave your cell phone in your pocket or the car. It can also ruin your night vision.

10. Enjoy nature

Relax and enjoy the night sky. Not every meteor shower is a winner. Sometimes, you may come away from a shower seeing only one meteor. But if that one meteor is bright, and takes a slow path across a starry night sky … it’ll be worth it.

To be successful at observing any meteor shower, you need to get into a kind of zen state, waiting and expecting the meteors to come to you, if you place yourself in a good position (country location, wide open sky) to see them.

Or forget the zen state, and let yourself be guided by this old meteor watcher’s motto:

You might see a lot or you might not see many, but if you stay in the house, you won’t see any.

Photos of meteors from EarthSky’s community

View at EarthSky Community Photos. | Tameem Altameemi of United Arab Emirates submitted this photo on December 14, 2024, and wrote: “My brother and I decided to go to an area away from light pollution between the mountains in UAE, and despite the moonlight that filled the place, we were able to see and photograph many meteors and fireballs. A special and completely clear night.” Thank you, Tameem!

View at EarthSky Community Photos. | Jeff Berkes in Assateague Island National Seashore, Maryland, shared this stunning image of a Geminid meteor he captured on December 14, 2024. Jeff wrote: “The wind was really blowing off the ocean, kicking up some nice waves, which created some minor erosion along the shoreline. I never let the moon or the cold keep me in for the Geminids!” Well done, Jeff!

View at EarthSky Community Photos. | Some of the stars of the Big Dipper are part of an open cluster called the Ursa Major Moving Group. On September 6, 2024, Susan Jensen captured this image and wrote: “Right place, right time! Standing on a gravel road in the middle of nowhere, looking across a stubble field. This slow-moving, vibrant meteor stopped me in my tracks! I was shooting the Big Dipper with the shutter locked to catch multiple frames for stacking when this monster did a slow flyby. How lucky that I was able to capture it!” Thank you, Susan!

Bottom line: Meteor showers are unpredictable but always a fun and relaxing time. Optimize your viewing with these tips.

Post your own photos at EarthSky Community Photos

When is the next meteor shower? Click here for EarthSky’s meteor shower guide

The post Meteor showers are here! 10 easy tips for watching first appeared on EarthSky.

from EarthSky https://ift.tt/2wzoFaR

You deserve a daily dose of good news. For the latest in science and the night sky, subscribe to EarthSky’s free daily newsletter.

Hooray! It’s meteor time! That’s right, the Lyrid meteor shower rambles across for a few weeks around April 22.

When is the next meteor shower? Click here for EarthSky’s meteor shower guide

So, how can you optimize your chances of seeing a great meteor display? Follow the tips below.

View at EarthSky Community Photos. | Jeremy Evans of California captured a Lyrid meteor zipping along the Milky Way on April 22, 2025. Jeremy wrote: “Lyrid meteor shower at peak activity. It was a quiet shower this year. I had my camera going all night and only caught one meteor. This single frame is from an all-night 1,200 frame time lapse on my front deck. I’m very fortunate to live under dark Bortle 2 skies. The glow on the horizon is from the last quarter moon just before rising. This meteor also left smoke trails.” Thank you, Jeremy.

1. Know the peak time

Generally, meteor showers happen over many days as Earth encounters a wide stream of icy particles in space. These particles are debris left behind by a comet. So the peak is a point in time when Earth is expected to encounter the greatest number of comet particles. To find the peak dates of meteor showers, check EarthSky’s meteor guide.

And here’s the catch … the peak of the shower comes at the same time for all of us on Earth. Meanwhile, our clocks are saying different times. You’ll often need to adjust from UTC to your local time.

However, the predictions are not always right on the money. And remember … it’s possible to see nice meteor displays in the hours – even days – before or after the predicted peak.

Also, keep in mind that meteor showers are part of nature. So naturally, they often defy prediction.

2. Location, location, location

We can’t say this strongly enough. It’s important to have a dark place to observe in the country. Visit EarthSky’s Best Places to Stargaze.

And … you need a wide-open view of the sky. A farmer’s field? Maybe a stretch of country road? Or a campsite with a clear view in one or more directions? That’s because an open sky will increase your chances of seeing some meteors.

3. Oh no! The moon is out

During a meteor shower, a bright moon is not your friend. In fact, nothing dampens the display of a meteor shower more effectively than a bright moon.

If the moon is out, look at areas of the sky away from the moon. Anything in the moon’s vicinity – including meteors – will likely be washed out by its bright light. And, another tip for watching in moonlight: place some object between yourself and the moon. Observing from the shadow of a barn, or vehicle, even a tree, can help you see more meteors. Basically, place yourself somewhere in the moon’s shadow.

4. Know the expected rate

Here, we touch on a topic that sometimes leads to some disappointment, especially among novice meteor-watchers: the rate.

Tables of meteor showers almost always list what is known as the zenithal hourly rate (ZHR) for each shower.

So the ZHR is the number of meteors you’ll see if you’re watching in a very dark sky, with the radiant overhead, when the shower is at its peak. In other words, the ZHR represents the number of meteors you might see per hour given the very best observing conditions during the shower’s maximum.

If the peak occurs when it’s still daylight at your location, if most of the meteors are predominantly faint, if a bright moon is out or if you’re located in a light-polluted area, the total number of meteors you see will be considerably reduced.

5. Don’t worry too much about radiant points

You don’t need to stare all night in a single direction – or even locate the radiant point – to have fun watching the shower. The meteors will appear all over the sky.

But … although you can see meteors shoot up from the horizon before a shower’s radiant rises, you’ll see more meteors after it rises. And you’ll see the most when the radiant is highest in the sky. So, find out the radiant point’s rising time. Then you can pinpoint the best time of night to watch the shower.

And … the radiant point is interesting. If you track meteors backward on the sky’s dome, you’ll find them streaming from their radiant point, a single point within a given constellation. Hence the meteor shower’s name.

6. Watch for an hour or more

Meteor showers will be better if you let your eyes adapt to the dark. That can take as long as 20 minutes. Plus, the meteors tend to come in spurts, followed by lulls. So, be patient! You’ll see some.

7. Notice the meteors’ speeds and colors

The Leonids are the swiftest meteors and the Taurids are the slowest meteors. The nice thing about a slow or medium speed meteor shower – such as the Lyrids – is if you see one and yell “meteor,” other people can catch it as well.

In fact, of the upcoming meteor showers … the Lyrids and the Delta Aquariids are medium speed showers. The Eta Aquariids and Perseids are swift meteors.

Plus, the April Lyrids, the December Geminids, and the August Perseids, can be colorful.

8. Watch for meteor trains

A meteor train is a persistent glow in the air left by some meteors after they have faded from view. Trains are from luminous ionized matter left in the wake of this incoming space debris. Some of the bright Lyrid meteors leave a persistent train. So you you might be lucky and see one.

9. Bring a blanket, a buddy, a hot drink and a lawn chair

A reclining lawn chair helps you lie back in comfort for an hour or more of meteor-watching.

If several of you are watching, take different parts of the sky. If you see one, shout “Meteor!” Dress warmly; the nights can be cool or cold, even during the summer months. You’ll probably appreciate that blanket and warm drink in the wee hours of the morning. Also, leave your laptops and tablets home; even using the nighttime dark mode will ruin your night vision. And this will be tough on some people: leave your cell phone in your pocket or the car. It can also ruin your night vision.

10. Enjoy nature

Relax and enjoy the night sky. Not every meteor shower is a winner. Sometimes, you may come away from a shower seeing only one meteor. But if that one meteor is bright, and takes a slow path across a starry night sky … it’ll be worth it.

To be successful at observing any meteor shower, you need to get into a kind of zen state, waiting and expecting the meteors to come to you, if you place yourself in a good position (country location, wide open sky) to see them.

Or forget the zen state, and let yourself be guided by this old meteor watcher’s motto:

You might see a lot or you might not see many, but if you stay in the house, you won’t see any.

Photos of meteors from EarthSky’s community

View at EarthSky Community Photos. | Tameem Altameemi of United Arab Emirates submitted this photo on December 14, 2024, and wrote: “My brother and I decided to go to an area away from light pollution between the mountains in UAE, and despite the moonlight that filled the place, we were able to see and photograph many meteors and fireballs. A special and completely clear night.” Thank you, Tameem!

View at EarthSky Community Photos. | Jeff Berkes in Assateague Island National Seashore, Maryland, shared this stunning image of a Geminid meteor he captured on December 14, 2024. Jeff wrote: “The wind was really blowing off the ocean, kicking up some nice waves, which created some minor erosion along the shoreline. I never let the moon or the cold keep me in for the Geminids!” Well done, Jeff!

View at EarthSky Community Photos. | Some of the stars of the Big Dipper are part of an open cluster called the Ursa Major Moving Group. On September 6, 2024, Susan Jensen captured this image and wrote: “Right place, right time! Standing on a gravel road in the middle of nowhere, looking across a stubble field. This slow-moving, vibrant meteor stopped me in my tracks! I was shooting the Big Dipper with the shutter locked to catch multiple frames for stacking when this monster did a slow flyby. How lucky that I was able to capture it!” Thank you, Susan!

Bottom line: Meteor showers are unpredictable but always a fun and relaxing time. Optimize your viewing with these tips.

Post your own photos at EarthSky Community Photos

When is the next meteor shower? Click here for EarthSky’s meteor shower guide

The post Meteor showers are here! 10 easy tips for watching first appeared on EarthSky.

from EarthSky https://ift.tt/2wzoFaR

Suspiciously similar planets could be a sign of alien life

A new study from researchers in Japan suggests that a better way to search for alien life might be to look for suspiciously similar planets that are close to each other. The idea is that if life has spread to neighboring planets, it would need to create a similar environment to its home planet in order to survive. Image via EarthSky with the help of AI.

• Searching for evidence of life on planets around other stars is difficult. A single detection of a certain chemical in an atmosphere or an unusual radio wave could be ambiguous and hard to verify.
• Scientists should look for patterns across groups of planets in a planetary system instead, researchers in Japan suggest.
• Such patterns on multiple planets might suggest that life has spread to neighboring planets and made the conditions more amenable to them. So these patterns could be an indicator of alien life.

Science news, night sky events and beautiful photos, all in one place. Click here to subscribe to our free daily newsletter.

Suspiciously similar planets could be a sign of alien life

Currently, scientists searching for life beyond Earth focus a lot on looking at the light coming from a distant planet, which reveals the makeup of its atmosphere. Or they listen for non-natural radio signals coming from space. But on April 15, 2026, a new study from researchers in Japan said scientists should look for signs of life in groups of planets that are suspiciously similar. Detecting patterns across a group of planets might suggest that life has spread from its home planet to neighboring planets and transformed them to accommodate their needs.

The current methods of looking for life through biosignatures (chemical or physical signs of life) or technosignatures (signs of alien technology) can be ambiguous. So a signature found among a cluster of planets would be stronger evidence than a single detection on one planet alone. The new model suggests that if life can spread between planets and affect their observable properties, then detecting this could be a robust signature of life, with few false positives.

When astronomers talk about life spreading between worlds, they call it panspermia. And the concept of altering a planet to suit an alien lifeform is called terraforming. Microbes that traveled via panspermia to another planet could alter the planet’s atmosphere or surface naturally. And an advanced alien civilization could terraform nearby planets artificially. Even humans have contemplated how we could someday terraform Mars to make it more habitable and earthlike.

Harrison B. Smith at the Earth-Life Science Institute, Institute of Science Tokyo, and Lana Sinapayen at Sony Computer Science Laboratories and National Institute for Basic Biology in Japan are the authors of the new study. They published their peer-reviewed findings in The Astrophysical Journal on April 9, 2026.

Our paper on detecting terraformed planets is finally published: doi.org/10.3847/1538…Context: we wanted a method to detect life in the universe that does not depend on any particular chemistry or hyperspecific definitions of life1/n#Astrobiology #ALife

— Lana Sinapayen (@sinalana.eurosky.social) 2026-04-10T01:21:28.458Z

An agnostic approach

The researchers are taking what they call an agnostic approach. That’s what they consider one not bound to any particular hypotheses or beliefs about alien life. So this approach seeks to overcome the limitations of of possible detections on single planets. Simple biosignatures are susceptible to false positives. Technosignatures are less susceptible, but they make strong assumptions about what kind of life could produce them.

Instead, the new approach seeks to find possible life signatures across multiple planets at a time. The signature could affect the observable properties of the planets in a similar way. Notably, this would be a stronger potential signature than on one single planet alone.

Basically, the approach is based on the assumption that life could spread between planets naturally. This is panspermia, where microbes or other cells could escape one planet – such as through an asteroid impact – and spread to other nearby planets.

In either of those two scenarios, life could alter the characteristics of the planets in similar ways. The statistical correlations between planet locations and their observable traits would be detectable.

View larger. | Some scientists think we could gradually terraform Mars in the future. That would be an example of intelligent life (humans) changing a nearby planet to be more like its own world. But even microbes could naturally change a planet through panspermia. Image via Daein Ballard/ Wikimedia Commons (CC BY-SA 3.0).

A broad definition of life

Sinapayen described the process on Bluesky, saying:

We wanted a method to detect life in the universe that does not depend on any particular chemistry or hyperspecific definitions of life. So we started with the broadest definition we could think of: Life self-replicates and mutates.

If a form of life landed upon a new planet and survived, it would change the environment on that planet in a way that makes it closer to the origin planet; think of trees producing oxygen, for example. That would be true whether the lifeform is a bacteria, a whole ecosystem, or characters from Andy Weir’s books.

Our question: Without knowing whether any single planet has life on it, could you at least detect that some planets seem suspiciously related? The answer (through simulations): under some conditions, you can make that detection with high certainty and no false positives. You can say ‘there is an X percent chance terraformation is happening’ and point to the planets that are driving that percentage up.

If life can travel to other planets and terraform them, those patterns will emerge between the locations of planets and their observable characteristics (for example, atmospheric composition). On the left, planets show no correlation between their locations and their characteristics. However, if life capable of panspermia and terraforming arises, then correlations emerge (right). In the model, life chooses its destination by looking for the planet with the most similar composition within some maximum distance. Image via Harrison B. Smith/ Earth-Life Science Institute (CC BY 4.0).

‘Something must be happening’

Sinapayen continued:

The best part is that it’s not just ‘oh, these planets look similar, something must be happening.’ Our method specifically picks out planets that seem to have an ‘ancestor to descendant’ relationship through ‘self replication with mutation.’ Because when life replicates with mutation in physical space, on average the parents and children will be closer both in space and in characteristics than the parents and the grandchildren, for example. So you’re looking for a correlation of location and characteristics, not just characteristics.

Harrison B. Smith at the Earth-Life Science Institute in Japan is a co-author of the new study about panspermia, terraforming and alien life. Image via Earth-Life Science Institute.

Lana Sinapayen at Sony Computer Science Laboratories and National Institute for Basic Biology in Japan is a co-author of the new study about panspermia, terraforming and alien life. Image via Google Scholar.

Planets most likely to host life

The researchers also developed a new method to determine which planets might be the most likely to be habitable or host life. They did so by clustering planets based on their observable characteristics and spatial relationships. This provided clues as to which groups of planets had a high probability of being influenced by life. Smith said:

By focusing on how life spreads and interacts with environments, we can search for it without needing a perfect definition or a single definitive signal.

Sinapayen added:

Even if life elsewhere is fundamentally different from life on Earth, its large-scale effects, such as spreading and modifying planets, may still leave detectable traces. That’s what makes this approach compelling.

Bottom line: A new study from Japan suggests we could search for a sign of alien life by looking for a group of planets that are suspiciously similar. Alien life that spreads to neighboring planets would likely transform each new planet to be like their home planet.

Source: An Agnostic Biosignature Based on Modeling Panspermia and Terraforming

Via Earth-Life Science Institute

Read more: Lifeforms can planet-hop on asteroids and survive

Read more: Can air pollution help us find alien life?

The post Suspiciously similar planets could be a sign of alien life first appeared on EarthSky.

from EarthSky https://ift.tt/M516xOK

A new study from researchers in Japan suggests that a better way to search for alien life might be to look for suspiciously similar planets that are close to each other. The idea is that if life has spread to neighboring planets, it would need to create a similar environment to its home planet in order to survive. Image via EarthSky with the help of AI.

• Searching for evidence of life on planets around other stars is difficult. A single detection of a certain chemical in an atmosphere or an unusual radio wave could be ambiguous and hard to verify.
• Scientists should look for patterns across groups of planets in a planetary system instead, researchers in Japan suggest.
• Such patterns on multiple planets might suggest that life has spread to neighboring planets and made the conditions more amenable to them. So these patterns could be an indicator of alien life.

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Suspiciously similar planets could be a sign of alien life

Currently, scientists searching for life beyond Earth focus a lot on looking at the light coming from a distant planet, which reveals the makeup of its atmosphere. Or they listen for non-natural radio signals coming from space. But on April 15, 2026, a new study from researchers in Japan said scientists should look for signs of life in groups of planets that are suspiciously similar. Detecting patterns across a group of planets might suggest that life has spread from its home planet to neighboring planets and transformed them to accommodate their needs.

The current methods of looking for life through biosignatures (chemical or physical signs of life) or technosignatures (signs of alien technology) can be ambiguous. So a signature found among a cluster of planets would be stronger evidence than a single detection on one planet alone. The new model suggests that if life can spread between planets and affect their observable properties, then detecting this could be a robust signature of life, with few false positives.

When astronomers talk about life spreading between worlds, they call it panspermia. And the concept of altering a planet to suit an alien lifeform is called terraforming. Microbes that traveled via panspermia to another planet could alter the planet’s atmosphere or surface naturally. And an advanced alien civilization could terraform nearby planets artificially. Even humans have contemplated how we could someday terraform Mars to make it more habitable and earthlike.

Harrison B. Smith at the Earth-Life Science Institute, Institute of Science Tokyo, and Lana Sinapayen at Sony Computer Science Laboratories and National Institute for Basic Biology in Japan are the authors of the new study. They published their peer-reviewed findings in The Astrophysical Journal on April 9, 2026.

Our paper on detecting terraformed planets is finally published: doi.org/10.3847/1538…Context: we wanted a method to detect life in the universe that does not depend on any particular chemistry or hyperspecific definitions of life1/n#Astrobiology #ALife

— Lana Sinapayen (@sinalana.eurosky.social) 2026-04-10T01:21:28.458Z

An agnostic approach

The researchers are taking what they call an agnostic approach. That’s what they consider one not bound to any particular hypotheses or beliefs about alien life. So this approach seeks to overcome the limitations of of possible detections on single planets. Simple biosignatures are susceptible to false positives. Technosignatures are less susceptible, but they make strong assumptions about what kind of life could produce them.

Instead, the new approach seeks to find possible life signatures across multiple planets at a time. The signature could affect the observable properties of the planets in a similar way. Notably, this would be a stronger potential signature than on one single planet alone.

Basically, the approach is based on the assumption that life could spread between planets naturally. This is panspermia, where microbes or other cells could escape one planet – such as through an asteroid impact – and spread to other nearby planets.

In either of those two scenarios, life could alter the characteristics of the planets in similar ways. The statistical correlations between planet locations and their observable traits would be detectable.

View larger. | Some scientists think we could gradually terraform Mars in the future. That would be an example of intelligent life (humans) changing a nearby planet to be more like its own world. But even microbes could naturally change a planet through panspermia. Image via Daein Ballard/ Wikimedia Commons (CC BY-SA 3.0).

A broad definition of life

Sinapayen described the process on Bluesky, saying:

We wanted a method to detect life in the universe that does not depend on any particular chemistry or hyperspecific definitions of life. So we started with the broadest definition we could think of: Life self-replicates and mutates.

If a form of life landed upon a new planet and survived, it would change the environment on that planet in a way that makes it closer to the origin planet; think of trees producing oxygen, for example. That would be true whether the lifeform is a bacteria, a whole ecosystem, or characters from Andy Weir’s books.

Our question: Without knowing whether any single planet has life on it, could you at least detect that some planets seem suspiciously related? The answer (through simulations): under some conditions, you can make that detection with high certainty and no false positives. You can say ‘there is an X percent chance terraformation is happening’ and point to the planets that are driving that percentage up.

If life can travel to other planets and terraform them, those patterns will emerge between the locations of planets and their observable characteristics (for example, atmospheric composition). On the left, planets show no correlation between their locations and their characteristics. However, if life capable of panspermia and terraforming arises, then correlations emerge (right). In the model, life chooses its destination by looking for the planet with the most similar composition within some maximum distance. Image via Harrison B. Smith/ Earth-Life Science Institute (CC BY 4.0).

‘Something must be happening’

Sinapayen continued:

The best part is that it’s not just ‘oh, these planets look similar, something must be happening.’ Our method specifically picks out planets that seem to have an ‘ancestor to descendant’ relationship through ‘self replication with mutation.’ Because when life replicates with mutation in physical space, on average the parents and children will be closer both in space and in characteristics than the parents and the grandchildren, for example. So you’re looking for a correlation of location and characteristics, not just characteristics.

Harrison B. Smith at the Earth-Life Science Institute in Japan is a co-author of the new study about panspermia, terraforming and alien life. Image via Earth-Life Science Institute.

Lana Sinapayen at Sony Computer Science Laboratories and National Institute for Basic Biology in Japan is a co-author of the new study about panspermia, terraforming and alien life. Image via Google Scholar.

Planets most likely to host life

The researchers also developed a new method to determine which planets might be the most likely to be habitable or host life. They did so by clustering planets based on their observable characteristics and spatial relationships. This provided clues as to which groups of planets had a high probability of being influenced by life. Smith said:

By focusing on how life spreads and interacts with environments, we can search for it without needing a perfect definition or a single definitive signal.

Sinapayen added:

Even if life elsewhere is fundamentally different from life on Earth, its large-scale effects, such as spreading and modifying planets, may still leave detectable traces. That’s what makes this approach compelling.

Bottom line: A new study from Japan suggests we could search for a sign of alien life by looking for a group of planets that are suspiciously similar. Alien life that spreads to neighboring planets would likely transform each new planet to be like their home planet.

Source: An Agnostic Biosignature Based on Modeling Panspermia and Terraforming

Via Earth-Life Science Institute

Read more: Lifeforms can planet-hop on asteroids and survive

Read more: Can air pollution help us find alien life?

The post Suspiciously similar planets could be a sign of alien life first appeared on EarthSky.

from EarthSky https://ift.tt/M516xOK

Simulating how black holes light up the dark

Artist’s depiction of a supermassive black hole tearing apart a star. Roughly half of the stellar debris gets flung back into space while the remainder forms a glowing accretion disk around the black hole. Researchers at Syracuse University have created new high-resolution simulations to show how black holes create streams of stellar debris. Image via DESY/ Science Communication Lab/ Syracuse University.

Science news, night sky events and beautiful photos, all in one place. Click here to subscribe to our free daily newsletter.

• When a star strays too close to a supermassive black hole, it gets torn apart. The debris accumulates to produce a brilliant flare called a tidal disruption event, or TDE.
• New high-resolution simulations confirm the stellar debris forms a narrow stream that encircles the black hole and collides with itself. Earlier models couldn’t capture this detail.
• Black hole spin may deflect the debris stream off course, offering a potential reason why no two TDEs look alike.

Syracuse University published this original story on April 9, 2026. Edits by EarthSky.

Simulating how black holes light up the dark

Supermassive black holes are among the most enigmatic objects in the universe. They typically weigh millions or even billions of times the mass of the sun. And they sit at the centers of most large galaxies. For example, at the heart of the Milky Way lies Sagittarius A*, our galaxy’s supermassive black hole. It has the mass of about 4 million suns. But these black holes do not emit light, so astronomers can only detect them indirectly through their effects on nearby stars and gas.

The Astrophysical Journal Letters published a new study on March 9, 2026. In it, co-author Eric Coughlin, assistant professor of physics in Syracuse University’s College of Arts and Sciences, and colleagues clarify what happens when a star wanders too close to one of these black holes and is torn apart.

When black holes capture stars

A star ingested by a supermassive black hole does not simply vanish in a single gulp. Instead, the black hole’s gravity tears the star into a long, thin debris stream. Over time, the debris stream wraps around the black hole. This is an effect that ultimately arises from Einstein’s General Theory of Relativity. Gravity according to Newton does not produce this effect.

When parts of that circling stream crash into one another, they release a burst of energy and subsequently accrete, or slowly spiral into, the black hole. Both of these effects – the initial collision and the subsequent accretion – produce so much radiation that they briefly outshine the entire galaxy in which they occur.

Astronomers refer to these events as tidal disruption events, or TDEs. TDEs offer one of the few ways to study supermassive black holes like Sagittarius A* in other galaxies. Coughlin said:

We can study tidal disruption events to learn more about black holes hidden from view.

For years, TDEs have fascinated researchers because each of these massive flares is like a fingerprint. By measuring how a flare rises, peaks and fades, scientists can infer properties of the black hole that produced it. These properties include its mass and perhaps its spin. But the details of how these flares form have remained difficult to pin down, in part because the process is hard to simulate accurately.

Seeing the debris clearly

That is where new high-resolution simulations are changing the picture. Recent work by a team led by Lucio Mayer at the University of Zurich uses a methodology known as smoothed particle hydrodynamics. This methodology decomposes a star into particles that interact with one another hydrodynamically. These are the same fundamental equations that govern the flow of water through a pipe.

Their study employed tens of billions of particles to model the disrupted star’s gas in unprecedented detail. The result is a superior view of what happens after a star gets ripped apart. Rather than dispersing chaotically, the debris forms a narrow, coherent stream that follows a predictable path around the black hole before crashing into itself.

Their finding supports a long-standing theoretical prediction. Earlier simulations often mischaracterized the stream’s structure because they lacked the resolution to capture such fine detail. This lead to a “spraying” of the stellar debris and unexpectedly high levels of fluid-dynamical dissipation. With far more particles and through the exploitation of graphics processing units on powerful supercomputers, the shape of the debris becomes much easier to see.

But the new models also reveal something else.

A 3D rendering of modeled debris particles. It highlights the self-intersection of the debris stream flow after a black hole rips apart a star. Image via Jean Favre, CSCS/ Lucio Mayer and Noah Kubli, University of Zurich/ Syracuse University.

The spin factor

Three properties of a supermassive black hole and the stellar orbit can influence the outcome of a given TDE: the black hole’s mass, how fast it spins, and the orientation of that spin relative to the orbital plane of the incoming debris. Together, they may determine when the flare begins, how bright it becomes and how long it lasts.

If the black hole is rotating, it induces additional variation in the spacetime around it compared to a non-spinning black hole. And that produces an effect known as nodal precession. This effect may shift the debris stream out of its original plane. So the stream may miss itself after one orbit, then miss again before finally colliding. In some cases, the flare may be delayed by several loops around the black hole.

No two are alike

That complication may help explain one of the enduring puzzles of TDE research. No two events look exactly alike. Some rise quickly and fade fast. Others unfold more slowly. Some are brighter, some dimmer. Some behave in ways that are still hard to classify. While differences in the mass of the black hole could account for some of these differences, these new simulations suggest that black hole spin may be one of the key reasons for that diversity.

TDEs turn invisible objects into readable signals. A star gets shredded, debris collides, light emerges and a previously hidden black hole is revealed. With better simulations and more powerful telescopes, astronomers are learning how to read those signals more clearly than ever before.

Bottom line: When black holes tear apart stars, the wreckage heats up, creating brilliant flares. And now new simulations are showing these flares with more detail than ever before.

Source: Tidal Disruption Events with SPH-EXA: Resolving the Return of the Stream

Via Syracuse University

Read more: Black hole belches radiation long after eating a star

The post Simulating how black holes light up the dark first appeared on EarthSky.

from EarthSky https://ift.tt/iGu6kS3

Artist’s depiction of a supermassive black hole tearing apart a star. Roughly half of the stellar debris gets flung back into space while the remainder forms a glowing accretion disk around the black hole. Researchers at Syracuse University have created new high-resolution simulations to show how black holes create streams of stellar debris. Image via DESY/ Science Communication Lab/ Syracuse University.

Science news, night sky events and beautiful photos, all in one place. Click here to subscribe to our free daily newsletter.

• When a star strays too close to a supermassive black hole, it gets torn apart. The debris accumulates to produce a brilliant flare called a tidal disruption event, or TDE.
• New high-resolution simulations confirm the stellar debris forms a narrow stream that encircles the black hole and collides with itself. Earlier models couldn’t capture this detail.
• Black hole spin may deflect the debris stream off course, offering a potential reason why no two TDEs look alike.

Syracuse University published this original story on April 9, 2026. Edits by EarthSky.

Simulating how black holes light up the dark

Supermassive black holes are among the most enigmatic objects in the universe. They typically weigh millions or even billions of times the mass of the sun. And they sit at the centers of most large galaxies. For example, at the heart of the Milky Way lies Sagittarius A*, our galaxy’s supermassive black hole. It has the mass of about 4 million suns. But these black holes do not emit light, so astronomers can only detect them indirectly through their effects on nearby stars and gas.

The Astrophysical Journal Letters published a new study on March 9, 2026. In it, co-author Eric Coughlin, assistant professor of physics in Syracuse University’s College of Arts and Sciences, and colleagues clarify what happens when a star wanders too close to one of these black holes and is torn apart.

When black holes capture stars

A star ingested by a supermassive black hole does not simply vanish in a single gulp. Instead, the black hole’s gravity tears the star into a long, thin debris stream. Over time, the debris stream wraps around the black hole. This is an effect that ultimately arises from Einstein’s General Theory of Relativity. Gravity according to Newton does not produce this effect.

When parts of that circling stream crash into one another, they release a burst of energy and subsequently accrete, or slowly spiral into, the black hole. Both of these effects – the initial collision and the subsequent accretion – produce so much radiation that they briefly outshine the entire galaxy in which they occur.

Astronomers refer to these events as tidal disruption events, or TDEs. TDEs offer one of the few ways to study supermassive black holes like Sagittarius A* in other galaxies. Coughlin said:

We can study tidal disruption events to learn more about black holes hidden from view.

For years, TDEs have fascinated researchers because each of these massive flares is like a fingerprint. By measuring how a flare rises, peaks and fades, scientists can infer properties of the black hole that produced it. These properties include its mass and perhaps its spin. But the details of how these flares form have remained difficult to pin down, in part because the process is hard to simulate accurately.

Seeing the debris clearly

That is where new high-resolution simulations are changing the picture. Recent work by a team led by Lucio Mayer at the University of Zurich uses a methodology known as smoothed particle hydrodynamics. This methodology decomposes a star into particles that interact with one another hydrodynamically. These are the same fundamental equations that govern the flow of water through a pipe.

Their study employed tens of billions of particles to model the disrupted star’s gas in unprecedented detail. The result is a superior view of what happens after a star gets ripped apart. Rather than dispersing chaotically, the debris forms a narrow, coherent stream that follows a predictable path around the black hole before crashing into itself.

Their finding supports a long-standing theoretical prediction. Earlier simulations often mischaracterized the stream’s structure because they lacked the resolution to capture such fine detail. This lead to a “spraying” of the stellar debris and unexpectedly high levels of fluid-dynamical dissipation. With far more particles and through the exploitation of graphics processing units on powerful supercomputers, the shape of the debris becomes much easier to see.

But the new models also reveal something else.

A 3D rendering of modeled debris particles. It highlights the self-intersection of the debris stream flow after a black hole rips apart a star. Image via Jean Favre, CSCS/ Lucio Mayer and Noah Kubli, University of Zurich/ Syracuse University.

The spin factor

Three properties of a supermassive black hole and the stellar orbit can influence the outcome of a given TDE: the black hole’s mass, how fast it spins, and the orientation of that spin relative to the orbital plane of the incoming debris. Together, they may determine when the flare begins, how bright it becomes and how long it lasts.

If the black hole is rotating, it induces additional variation in the spacetime around it compared to a non-spinning black hole. And that produces an effect known as nodal precession. This effect may shift the debris stream out of its original plane. So the stream may miss itself after one orbit, then miss again before finally colliding. In some cases, the flare may be delayed by several loops around the black hole.

No two are alike

That complication may help explain one of the enduring puzzles of TDE research. No two events look exactly alike. Some rise quickly and fade fast. Others unfold more slowly. Some are brighter, some dimmer. Some behave in ways that are still hard to classify. While differences in the mass of the black hole could account for some of these differences, these new simulations suggest that black hole spin may be one of the key reasons for that diversity.

TDEs turn invisible objects into readable signals. A star gets shredded, debris collides, light emerges and a previously hidden black hole is revealed. With better simulations and more powerful telescopes, astronomers are learning how to read those signals more clearly than ever before.

Bottom line: When black holes tear apart stars, the wreckage heats up, creating brilliant flares. And now new simulations are showing these flares with more detail than ever before.

Source: Tidal Disruption Events with SPH-EXA: Resolving the Return of the Stream

Via Syracuse University

Read more: Black hole belches radiation long after eating a star

The post Simulating how black holes light up the dark first appeared on EarthSky.

from EarthSky https://ift.tt/iGu6kS3