Equatorial plasma bubbles and their effect on air travel

View at EarthSky Community Photos. | Muhammad Rayhan in Jakarta, Indonesia, captured this image on February 5, 2023. Muhammad wrote: “The smallest full moon of the year photobombed by a commercial airplane that is about to land at the nearby airport.” Thank you, Muhammad! Indonesia is a country on the equator. And new study has just looked at something called equatorial plasma bubbles, which occur high in Earth’s ionosphere, disrupting aircraft communication and navigation for planes in and around Earth’s equatorial regions, especially during landings.

Equatorial plasma bubbles disrupt air traffic communications

Earth’s atmosphere contains some powerful phenomena, and not just storms like hurricanes or blizzards. For example, Earth’s upper atmosphere features a fascinating phenomenon known as equatorial plasma bubbles. These lower-density pockets reside in Earth’s ionosphere – starting roughly 50 miles (80 km) above Earth’s surface – in the region wrapping above Earth’s equator. The bubbles aren’t visible to human eyes. But they can pose risks to aircraft communications and ultimately passenger safety. Scientists from the Hong Kong Polytechnic University said in a news release at Eurekalert on December 11, 2024, that they’ve developed a new 3D model related to these equatorial plasma bubbles. They’re trying to determine just how the bubbles disrupt navigation in aviation. And they’re trying to make aircraft systems more resilient to this type of interference.

Lead researcher Yiping Jiang of the Hong Kong Polytechnic University said in EurekaAlert:

Our model provides a comprehensive assessment of the risks posed by equatorial plasma bubbles, which is essential for improving the safe operation of ground-based systems in areas affected by these ionospheric disturbances. This research is a crucial step forward in enhancing aviation safety, particularly in regions like Hong Kong, where equatorial plasma bubbles are a frequent concern.

The researchers published their peer-reviewed study in the journal Satellite Navigation on December 2, 2024.

Looking for a New Year’s gift for someone who loves astronomy? The 2025 EarthSky Lunar Calendar is just the thing! A unique and beautiful poster-sized calendar, showing moon phases for every night of the year. Get yours today!

What are equatorial plasma bubbles?

Equatorial plasma bubbles are an atmospheric feature that occur at night above and around the Earth’s magnetic equator. The magnetic equator is tilted just a bit from the geographic equator. So, these features are more common above the part of Earth’s surface on and near the equator.

Equatorial plasma bubbles form high up above Earth’s surface within the ionosphere, a layer of the atmosphere vital to aircraft communications. The ionosphere takes its name from the fact that the atmosphere and molecules here are ionized by solar radiation. That means an atom or molecule gains a positive or negative charge. The ionosphere plays a role in the movement of radio signals. This part of the atmosphere reflects high-frequency (HF) radio waves, enabling long-range communication between aircraft, especially over oceans, where line-of-sight communication isn’t possible. The ionosphere lets radio signals “bounce” back to Earth beyond the horizon. So the ionosphere is key to long-distance communication between aircraft and the ground.

View larger. | The layers of Earth’s atmosphere and the relationship to the ionosphere. Image via NASA.

How and when do equatorial plasma bubbles form?

After the sun sets on a given part of Earth, ionization in Earth’s upper atmosphere decreases dramatically. No sunlight, no ionization. And that’s when the equatorial plasma bubbles form. As positive and negative ions recombine, they create a layer of lower-density air. This less-dense air layer rises through more heavily ionized layers above, due to convection (the same process that creates bubbles in a pan of boiling water). The rising motion in Earth’s upper air creates a turbulent, bubble-like structure.

Equatorial plasma bubbles can be quite large, some 62 miles (100 km) in scale. And equatorial plasma bubbles can form throughout the year. For example, they’re common in Northern Australia from February to April and August to October.

How do they affect people and technology?

Equatorial plasma bubbles can change the movement of radio signals, resulting in communication delays. For example, the Global Positioning System (GPS) is a space-based radio-navigation system. People use it for aviation and other navigation. It normally provides a 3D position to meter-level accuracy and time to the 10-nanosecond level. This coverage is at all times of the day and night and anywhere on Earth. But the presence of equatorial plasma bubbles affects GPS location and time accuracy. These bubbles can disable radio communications and lower GPS performance.

Equatorial plasma bubbles can also affect the ability of ground-based augmentation systems, like receivers and antennas at airports. They interrupt GPS location measurements that ensure safe, precision flight operations. Air traffic controllers and pilots use ground-based augmentation systems to correct and improve the accuracy of aircraft GPS positioning in the vicinity of airports. Computer systems onboard aircraft receive both GPS signals and ground-based corrections. These ground-based systems provide support for aircraft moving from open airspace to precision approach and landing. GPS disruptions have the potential to impact this fine-tuned process.

What the study found

What the researchers found is that these ground-based systems can maintain their integrity when equatorial plasma bubbles disrupt their signals. So current systems remain useful in detecting and mitigating against the communication delays caused by equatorial plasma bubbles. Effective monitoring to detect and reduce potential communication delays caused by equatorial plasma bubbles can ensure continued effectiveness of aircraft navigation systems in these equatorial regions.

Equatorial plasma bubbles are not a direct threat to people. But the world’s reliance on radio-based technology makes them relevant to aviation safety. And the study’s authors hope their new 3D model will help in practical applications, so that aviation systems can continue to meet the highest safety standards worldwide.

Bottom line: Equatorial plasma bubbles are pockets of low density in the Earth’s ionosphere in regions around the equator. They pose risks to aircraft by disrupting radio-based navigation systems. However, research shows that while equatorial plasma bubbles can be disruptive, ground-based systems are still useful in limiting effects on aviation activities.

Source: Equatorial plasma bubble model and integrity risk evaluation for ground based augmentation system in Hong Kong

Via EurekaAlert

The post Equatorial plasma bubbles and their effect on air travel first appeared on EarthSky.

from EarthSky https://ift.tt/DjhFKW1

View at EarthSky Community Photos. | Muhammad Rayhan in Jakarta, Indonesia, captured this image on February 5, 2023. Muhammad wrote: “The smallest full moon of the year photobombed by a commercial airplane that is about to land at the nearby airport.” Thank you, Muhammad! Indonesia is a country on the equator. And new study has just looked at something called equatorial plasma bubbles, which occur high in Earth’s ionosphere, disrupting aircraft communication and navigation for planes in and around Earth’s equatorial regions, especially during landings.

Equatorial plasma bubbles disrupt air traffic communications

Earth’s atmosphere contains some powerful phenomena, and not just storms like hurricanes or blizzards. For example, Earth’s upper atmosphere features a fascinating phenomenon known as equatorial plasma bubbles. These lower-density pockets reside in Earth’s ionosphere – starting roughly 50 miles (80 km) above Earth’s surface – in the region wrapping above Earth’s equator. The bubbles aren’t visible to human eyes. But they can pose risks to aircraft communications and ultimately passenger safety. Scientists from the Hong Kong Polytechnic University said in a news release at Eurekalert on December 11, 2024, that they’ve developed a new 3D model related to these equatorial plasma bubbles. They’re trying to determine just how the bubbles disrupt navigation in aviation. And they’re trying to make aircraft systems more resilient to this type of interference.

Lead researcher Yiping Jiang of the Hong Kong Polytechnic University said in EurekaAlert:

Our model provides a comprehensive assessment of the risks posed by equatorial plasma bubbles, which is essential for improving the safe operation of ground-based systems in areas affected by these ionospheric disturbances. This research is a crucial step forward in enhancing aviation safety, particularly in regions like Hong Kong, where equatorial plasma bubbles are a frequent concern.

The researchers published their peer-reviewed study in the journal Satellite Navigation on December 2, 2024.

Looking for a New Year’s gift for someone who loves astronomy? The 2025 EarthSky Lunar Calendar is just the thing! A unique and beautiful poster-sized calendar, showing moon phases for every night of the year. Get yours today!

What are equatorial plasma bubbles?

Equatorial plasma bubbles are an atmospheric feature that occur at night above and around the Earth’s magnetic equator. The magnetic equator is tilted just a bit from the geographic equator. So, these features are more common above the part of Earth’s surface on and near the equator.

Equatorial plasma bubbles form high up above Earth’s surface within the ionosphere, a layer of the atmosphere vital to aircraft communications. The ionosphere takes its name from the fact that the atmosphere and molecules here are ionized by solar radiation. That means an atom or molecule gains a positive or negative charge. The ionosphere plays a role in the movement of radio signals. This part of the atmosphere reflects high-frequency (HF) radio waves, enabling long-range communication between aircraft, especially over oceans, where line-of-sight communication isn’t possible. The ionosphere lets radio signals “bounce” back to Earth beyond the horizon. So the ionosphere is key to long-distance communication between aircraft and the ground.

View larger. | The layers of Earth’s atmosphere and the relationship to the ionosphere. Image via NASA.

How and when do equatorial plasma bubbles form?

After the sun sets on a given part of Earth, ionization in Earth’s upper atmosphere decreases dramatically. No sunlight, no ionization. And that’s when the equatorial plasma bubbles form. As positive and negative ions recombine, they create a layer of lower-density air. This less-dense air layer rises through more heavily ionized layers above, due to convection (the same process that creates bubbles in a pan of boiling water). The rising motion in Earth’s upper air creates a turbulent, bubble-like structure.

Equatorial plasma bubbles can be quite large, some 62 miles (100 km) in scale. And equatorial plasma bubbles can form throughout the year. For example, they’re common in Northern Australia from February to April and August to October.

How do they affect people and technology?

Equatorial plasma bubbles can change the movement of radio signals, resulting in communication delays. For example, the Global Positioning System (GPS) is a space-based radio-navigation system. People use it for aviation and other navigation. It normally provides a 3D position to meter-level accuracy and time to the 10-nanosecond level. This coverage is at all times of the day and night and anywhere on Earth. But the presence of equatorial plasma bubbles affects GPS location and time accuracy. These bubbles can disable radio communications and lower GPS performance.

Equatorial plasma bubbles can also affect the ability of ground-based augmentation systems, like receivers and antennas at airports. They interrupt GPS location measurements that ensure safe, precision flight operations. Air traffic controllers and pilots use ground-based augmentation systems to correct and improve the accuracy of aircraft GPS positioning in the vicinity of airports. Computer systems onboard aircraft receive both GPS signals and ground-based corrections. These ground-based systems provide support for aircraft moving from open airspace to precision approach and landing. GPS disruptions have the potential to impact this fine-tuned process.

What the study found

What the researchers found is that these ground-based systems can maintain their integrity when equatorial plasma bubbles disrupt their signals. So current systems remain useful in detecting and mitigating against the communication delays caused by equatorial plasma bubbles. Effective monitoring to detect and reduce potential communication delays caused by equatorial plasma bubbles can ensure continued effectiveness of aircraft navigation systems in these equatorial regions.

Equatorial plasma bubbles are not a direct threat to people. But the world’s reliance on radio-based technology makes them relevant to aviation safety. And the study’s authors hope their new 3D model will help in practical applications, so that aviation systems can continue to meet the highest safety standards worldwide.

Bottom line: Equatorial plasma bubbles are pockets of low density in the Earth’s ionosphere in regions around the equator. They pose risks to aircraft by disrupting radio-based navigation systems. However, research shows that while equatorial plasma bubbles can be disruptive, ground-based systems are still useful in limiting effects on aviation activities.

Source: Equatorial plasma bubble model and integrity risk evaluation for ground based augmentation system in Hong Kong

Via EurekaAlert

The post Equatorial plasma bubbles and their effect on air travel first appeared on EarthSky.

from EarthSky https://ift.tt/DjhFKW1

Deep-sky photos for December 2024: Editor’s picks

View at EarthSky Community Photos. | Robert Pettengill in Austin, Texas (and 2 other locations), captured the Rosette nebula in Monoceros on December 22, 2024. Robert wrote: “A long-exposure image of the Rosette Nebula on 5 nights in December from Tucson, Austin and Bad Wolf Ranch.” Beautiful! Thank you, Robert. See more deep-sky photos from December below.

Stunning deep-sky photos from our community

The EarthSky community has many talented astrophotographers who capture stunning images of the deep sky. We gathered some of our favorite deep-sky photos we received in December 2024 for you to enjoy. Do you have some of your own deep-sky images to share? You can submit them to us here. We love to see them!

The 2025 EarthSky Lunar Calendar is now for sale. Get yours today!

Deep-sky photos of diffuse nebulae

View at EarthSky Community Photos. | Steven Bellavia in Smithfield, Virginia, captured Thor’s Helmet on December 30, 2024. Steven wrote: “Thor’s Helmet is an emission nebula that glows from the energetic winds of Wolf-Rayet star WR7. It resides 12,000 light-years away in the constellation Canis Major, the larger of Orion’s 2 hunting dogs.” Thank you, Steven!

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured IC443, the Jellyfish nebula in the constellation Gemini, on December 7, 2024. Andy wrote: “I had never read about or seen pics of this nebula. I was just wandering around in Stellarium and said ‘Wow, that looks interesting.’ And so it is. This is a supernova remnant from 30,000-35,000 years ago. It is 5,000 light-years away. There is so much cool stuff in space. Doesn’t the bright red part look like a jellyfish?” Thank you, Andy!

View at EarthSky Community Photos. | Shaurya Salunkhe in Pune, Maharashtra, India, caught Messier 42, the Orion nebula, on December 7, 2024. Shaurya wrote: “The Orion Nebula, located approximately 1,344 light-years away in Orion’s Sword. It is one of the brightest nebulae visible in the night sky. It is the closest region of massive star formation to Earth.” Thank you, Shaurya!

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured NGC 1333, the Embryo nebula, on December 29, 2024. Andy wrote: “Embryo Nebula, located in Perseus, 980 to 1,140 light-years away. Notice the dark nebulae (upper right and lower left).” Thank you, Andy!

Planetary nebulae

View at EarthSky Community Photos. | Steven Bellavia in Smithfield, Virginia, captured the Bear Claw nebula on December 3, 2024. Steven wrote: “The Bear Claw nebula is a large but very faint planetary nebula in Cassiopeia. Astronomer Stewart Sharpless first discovered this nebula in 1959 and included it in his catalog of HII regions under the name of Sh2-200.” Thank you, Steven!

View at EarthSky Community Photos. | Scott Smith in Palmetto, Florida, captured the Helix nebula in Aquarius on December 19, 2024. Scott wrote: “The Helix nebula, often called the Eye of God, is a planetary nebula that’s the result of a dying star. The Helix nebula is the remains of a star that’s nearing the end of its life and has blown off its outer layers of gas. The remaining core of the star is a white dwarf, which is a small, hot, dense remnant.” Thank you, Scott!

A star cluster and a nebula

View at EarthSky Community Photos. | Rounak Mohanty in Cuttack, Odisha, India, captured the constellations Taurus and Perseus on December 22, 2024. Rounak wrote: “This is picture of the California nebula and Pleiades and surroundings in a single frame.” Thank you, Rounak!

A handful of external galaxies

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured galaxies Messier 81 and Messier 82 in Ursa Major on December 29, 2024. Andy wrote: “These 2 galaxies, while not large objects (like Andromeda), are bright and thus relatively easy to photograph, plus the difference between the 2 makes it all the more interesting.” Thank you, Andy!

View at EarthSky Community Photos. | Mohammed Abdallah in Suez, Egypt, captured the Andromeda galaxy on December 16, 2024. Mohammed wrote: “Andromeda, M31, our largest neighbor galaxy, shot from my backyard in Bortle 8, Suez. I reprocessed this shot many times but the end result is quite satisfying.” Thank you, Mohammed!

And two supernovae in distant galaxies

View at EarthSky Community Photos. | Eliot Herman in Tucson, Arizona, used a large remote telescope in Utah to make these images of Supernova 2024aeee and Supernova 2024aecx on December 19, 2024. Eliot wrote: “Two nice supernovae were discovered during the Cold Full Moon period. Both visible in the Northern Hemisphere. SN2024aeee in galaxy NGC 2523 was discovered December 17, 2024 (left), and Supernova 2024aecx in galaxy NGC 3521 was discovered December 16, 2024 (right).” Thank you, Eliot!

Bottom line: Enjoy this gallery of deep-sky photos for December 2024 from our EarthSky community. If you have a great photo to share, send it in, too. We love to see them!

Share your recent Earth or sky photo at EarthSky Community Photos.

The post Deep-sky photos for December 2024: Editor’s picks first appeared on EarthSky.

from EarthSky https://ift.tt/IOs9Hce

View at EarthSky Community Photos. | Robert Pettengill in Austin, Texas (and 2 other locations), captured the Rosette nebula in Monoceros on December 22, 2024. Robert wrote: “A long-exposure image of the Rosette Nebula on 5 nights in December from Tucson, Austin and Bad Wolf Ranch.” Beautiful! Thank you, Robert. See more deep-sky photos from December below.

Stunning deep-sky photos from our community

The EarthSky community has many talented astrophotographers who capture stunning images of the deep sky. We gathered some of our favorite deep-sky photos we received in December 2024 for you to enjoy. Do you have some of your own deep-sky images to share? You can submit them to us here. We love to see them!

The 2025 EarthSky Lunar Calendar is now for sale. Get yours today!

Deep-sky photos of diffuse nebulae

View at EarthSky Community Photos. | Steven Bellavia in Smithfield, Virginia, captured Thor’s Helmet on December 30, 2024. Steven wrote: “Thor’s Helmet is an emission nebula that glows from the energetic winds of Wolf-Rayet star WR7. It resides 12,000 light-years away in the constellation Canis Major, the larger of Orion’s 2 hunting dogs.” Thank you, Steven!

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured IC443, the Jellyfish nebula in the constellation Gemini, on December 7, 2024. Andy wrote: “I had never read about or seen pics of this nebula. I was just wandering around in Stellarium and said ‘Wow, that looks interesting.’ And so it is. This is a supernova remnant from 30,000-35,000 years ago. It is 5,000 light-years away. There is so much cool stuff in space. Doesn’t the bright red part look like a jellyfish?” Thank you, Andy!

View at EarthSky Community Photos. | Shaurya Salunkhe in Pune, Maharashtra, India, caught Messier 42, the Orion nebula, on December 7, 2024. Shaurya wrote: “The Orion Nebula, located approximately 1,344 light-years away in Orion’s Sword. It is one of the brightest nebulae visible in the night sky. It is the closest region of massive star formation to Earth.” Thank you, Shaurya!

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured NGC 1333, the Embryo nebula, on December 29, 2024. Andy wrote: “Embryo Nebula, located in Perseus, 980 to 1,140 light-years away. Notice the dark nebulae (upper right and lower left).” Thank you, Andy!

Planetary nebulae

View at EarthSky Community Photos. | Steven Bellavia in Smithfield, Virginia, captured the Bear Claw nebula on December 3, 2024. Steven wrote: “The Bear Claw nebula is a large but very faint planetary nebula in Cassiopeia. Astronomer Stewart Sharpless first discovered this nebula in 1959 and included it in his catalog of HII regions under the name of Sh2-200.” Thank you, Steven!

View at EarthSky Community Photos. | Scott Smith in Palmetto, Florida, captured the Helix nebula in Aquarius on December 19, 2024. Scott wrote: “The Helix nebula, often called the Eye of God, is a planetary nebula that’s the result of a dying star. The Helix nebula is the remains of a star that’s nearing the end of its life and has blown off its outer layers of gas. The remaining core of the star is a white dwarf, which is a small, hot, dense remnant.” Thank you, Scott!

A star cluster and a nebula

View at EarthSky Community Photos. | Rounak Mohanty in Cuttack, Odisha, India, captured the constellations Taurus and Perseus on December 22, 2024. Rounak wrote: “This is picture of the California nebula and Pleiades and surroundings in a single frame.” Thank you, Rounak!

A handful of external galaxies

View at EarthSky Community Photos. | Andy Dungan near Cotopaxi, Colorado, captured galaxies Messier 81 and Messier 82 in Ursa Major on December 29, 2024. Andy wrote: “These 2 galaxies, while not large objects (like Andromeda), are bright and thus relatively easy to photograph, plus the difference between the 2 makes it all the more interesting.” Thank you, Andy!

View at EarthSky Community Photos. | Mohammed Abdallah in Suez, Egypt, captured the Andromeda galaxy on December 16, 2024. Mohammed wrote: “Andromeda, M31, our largest neighbor galaxy, shot from my backyard in Bortle 8, Suez. I reprocessed this shot many times but the end result is quite satisfying.” Thank you, Mohammed!

And two supernovae in distant galaxies

View at EarthSky Community Photos. | Eliot Herman in Tucson, Arizona, used a large remote telescope in Utah to make these images of Supernova 2024aeee and Supernova 2024aecx on December 19, 2024. Eliot wrote: “Two nice supernovae were discovered during the Cold Full Moon period. Both visible in the Northern Hemisphere. SN2024aeee in galaxy NGC 2523 was discovered December 17, 2024 (left), and Supernova 2024aecx in galaxy NGC 3521 was discovered December 16, 2024 (right).” Thank you, Eliot!

Bottom line: Enjoy this gallery of deep-sky photos for December 2024 from our EarthSky community. If you have a great photo to share, send it in, too. We love to see them!

Share your recent Earth or sky photo at EarthSky Community Photos.

The post Deep-sky photos for December 2024: Editor’s picks first appeared on EarthSky.

from EarthSky https://ift.tt/IOs9Hce

When you wish upon a star, is it already dead?

Have you ever looked up on a clear night and wished upon a star? Cynics have been known to say that the star you wished on was probably already dead … but is that true? Image via ESO/ Luis Calçada/ Herbert Zodet.

By Laura Nicole Driessen, University of Sydney

When you wish upon a star, is it already dead?

When you wish upon a star, Jiminy Cricket told us, your dreams come true. But according to an idea doing the rounds on social media, that may not be the case:

According to astronomy, when you wish upon a star you’re a million years too late. The star is dead, just like your dreams.

Is that really true? Did Jiminy Cricket lie to us?

As an astronomer, I’m happy to say that the stars we can see in the night sky are a lot closer and live a lot longer than you would think. It’s pretty unlikely you’ve accidentally wished upon a star that’s already dead.

The 2025 EarthSky Lunar Calendar is now available! A unique and beautiful poster-sized calendar. Get yours today!

Stars are closer than you think

When someone hits you with the depressing factoid that the stars we wish on are already dead, they usually start by saying something about how the stars are “millions of light-years away.” This means the light from the star has been travelling for millions of years to reach your eyes, so by now the star is millions of years older and – supposedly – most likely dead.

But the stars you’re wishing on probably aren’t that far away. All the stars we can see with our eyes are inside our galaxy, the Milky Way. The Milky Way is approximately 100,000 light-years across, and our solar system is about 26,000 light-years from the center of the galaxy.

So if we could see the stars at the very far edge of the galaxy, they’d still only be about 74,000 light-years away. That’s nowhere near a million light-years away, let alone “millions of light-years.”

Artist’s concept of the Milky Way as seen from above. The location of our sun is labeled below center, about halfway out to the edge of the galaxy. Image via NASA/ JPL-Caltech/ R. Hurt (SSC/ Caltech).

Visible stars are even closer

In practice, the stars we can see aren’t even that far away. On a dark night, with no moon and with good vision, the faintest star we can see with our eyes has a brightness of around magnitude 6.5.

Brighter stars have lower magnitudes, and dimmer stars have higher ones. The brightest star in the Southern Cross has a magnitude of 0.8, while the faintest star in the Southern Cross has a magnitude of 3.6.

The visible brightness limit of magnitude 6.5 means we can only see stars out to around 10,000 light-years from Earth. So if you happen to wish on one of the more distant stars, the light has travelled 10,000 years to hit your eye.

And if we assume wishes travel at the speed of light, it’ll take another 10,000 years to reach the star. So even the most distant visible star is only 20,000 years older by the time your wish reaches it.

So the question is: do stars live longer than 20,000 years?

Image of the Southern Cross (the 4 bright stars on the right) and the ‘pointer stars’ (the 2 bright stars on the left). The brightest star in the Southern Cross, Alpha Crucis or ACrux (the bottom of the cross), is 321 light-years away. The faintest star, Delta Crucis (right), is 228 light-years away. The pointer stars are Alpha Centauri (leftmost bright star, around 4 light-years away) and Beta Centauri (around 390 light-years away). Image via ESO/ S. Brunier

Stars live longer than you think

The Yale Bright Star Catalog contains 9,096 stars that are brighter than magnitude 7, placing them roughly in the limit of what our eyes can see. And 40% of the stars in the catalog are so-called giant stars, which come in three varieties: normal giants, bright giants and super giants.

The more massive the star, the shorter its life. So these giant stars are here for a good time, not a long time.

But in astronomy, a “good time” is still at least a few hundred thousand years, much longer than your wish needs to arrive at a star closer than 10,000 light-years away.

The rest of the visible stars are what are called main sequence (or mid-life) stars and sub-giant stars. These stick around a lot longer, up to a few billion years. So when it comes to wishes, age is just a (really big) number.

Sirius A, the brightest star in the night sky and second closest star to the sun, and its fainter companion Sirius B. This image was taken using the Hubble Space Telescope. Image via Hubblesite.

When you wish upon a star, choose one of these

If you’re still feeling a bit nervous about wishing upon a dead star, there are a few safe bets.

Alpha Centauri is the closest star to Earth and the 4th brightest star in the sky. Even better, it’s actually three stars, and they’re only about 4 light-years away. They’ll definitely last longer than the eight years needed for their light to reach you and your wish to reach them.

The brightest star in the sky, Sirius, is a main sequence star only 8.6 light-years away. Epsilon Eridani is approximately 10 light-years away. It’s similar to our sun and a little under a billion years old. Since Sirius and Epsilon Eridani are in their mid-life, they still have millions – maybe even billions – of years left to burn.

The safest star to send your wishes to? The sun! The sun is only 8 light-minutes away, and it’ll be a main-sequence star for around five billion years yet.

So when you wish upon a star, that star is less than 10,000 light-years away and will probably live for at least hundreds of thousands of years … and maybe millions or even billions of years (just like your dreams).

Laura Nicole Driessen, Postdoctoral Researcher in Radio Astronomy, University of Sydney

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Bottom line: Some cynics say that when you wish upon a star, that star is already dead. But don’t listen to them! The stars you can see, and your dreams, are perfectly safe.

The post When you wish upon a star, is it already dead? first appeared on EarthSky.

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Have you ever looked up on a clear night and wished upon a star? Cynics have been known to say that the star you wished on was probably already dead … but is that true? Image via ESO/ Luis Calçada/ Herbert Zodet.

By Laura Nicole Driessen, University of Sydney

When you wish upon a star, is it already dead?

When you wish upon a star, Jiminy Cricket told us, your dreams come true. But according to an idea doing the rounds on social media, that may not be the case:

According to astronomy, when you wish upon a star you’re a million years too late. The star is dead, just like your dreams.

Is that really true? Did Jiminy Cricket lie to us?

As an astronomer, I’m happy to say that the stars we can see in the night sky are a lot closer and live a lot longer than you would think. It’s pretty unlikely you’ve accidentally wished upon a star that’s already dead.

The 2025 EarthSky Lunar Calendar is now available! A unique and beautiful poster-sized calendar. Get yours today!

Stars are closer than you think

When someone hits you with the depressing factoid that the stars we wish on are already dead, they usually start by saying something about how the stars are “millions of light-years away.” This means the light from the star has been travelling for millions of years to reach your eyes, so by now the star is millions of years older and – supposedly – most likely dead.

But the stars you’re wishing on probably aren’t that far away. All the stars we can see with our eyes are inside our galaxy, the Milky Way. The Milky Way is approximately 100,000 light-years across, and our solar system is about 26,000 light-years from the center of the galaxy.

So if we could see the stars at the very far edge of the galaxy, they’d still only be about 74,000 light-years away. That’s nowhere near a million light-years away, let alone “millions of light-years.”

Artist’s concept of the Milky Way as seen from above. The location of our sun is labeled below center, about halfway out to the edge of the galaxy. Image via NASA/ JPL-Caltech/ R. Hurt (SSC/ Caltech).

Visible stars are even closer

In practice, the stars we can see aren’t even that far away. On a dark night, with no moon and with good vision, the faintest star we can see with our eyes has a brightness of around magnitude 6.5.

Brighter stars have lower magnitudes, and dimmer stars have higher ones. The brightest star in the Southern Cross has a magnitude of 0.8, while the faintest star in the Southern Cross has a magnitude of 3.6.

The visible brightness limit of magnitude 6.5 means we can only see stars out to around 10,000 light-years from Earth. So if you happen to wish on one of the more distant stars, the light has travelled 10,000 years to hit your eye.

And if we assume wishes travel at the speed of light, it’ll take another 10,000 years to reach the star. So even the most distant visible star is only 20,000 years older by the time your wish reaches it.

So the question is: do stars live longer than 20,000 years?

Image of the Southern Cross (the 4 bright stars on the right) and the ‘pointer stars’ (the 2 bright stars on the left). The brightest star in the Southern Cross, Alpha Crucis or ACrux (the bottom of the cross), is 321 light-years away. The faintest star, Delta Crucis (right), is 228 light-years away. The pointer stars are Alpha Centauri (leftmost bright star, around 4 light-years away) and Beta Centauri (around 390 light-years away). Image via ESO/ S. Brunier

Stars live longer than you think

The Yale Bright Star Catalog contains 9,096 stars that are brighter than magnitude 7, placing them roughly in the limit of what our eyes can see. And 40% of the stars in the catalog are so-called giant stars, which come in three varieties: normal giants, bright giants and super giants.

The more massive the star, the shorter its life. So these giant stars are here for a good time, not a long time.

But in astronomy, a “good time” is still at least a few hundred thousand years, much longer than your wish needs to arrive at a star closer than 10,000 light-years away.

The rest of the visible stars are what are called main sequence (or mid-life) stars and sub-giant stars. These stick around a lot longer, up to a few billion years. So when it comes to wishes, age is just a (really big) number.

Sirius A, the brightest star in the night sky and second closest star to the sun, and its fainter companion Sirius B. This image was taken using the Hubble Space Telescope. Image via Hubblesite.

When you wish upon a star, choose one of these

If you’re still feeling a bit nervous about wishing upon a dead star, there are a few safe bets.

Alpha Centauri is the closest star to Earth and the 4th brightest star in the sky. Even better, it’s actually three stars, and they’re only about 4 light-years away. They’ll definitely last longer than the eight years needed for their light to reach you and your wish to reach them.

The brightest star in the sky, Sirius, is a main sequence star only 8.6 light-years away. Epsilon Eridani is approximately 10 light-years away. It’s similar to our sun and a little under a billion years old. Since Sirius and Epsilon Eridani are in their mid-life, they still have millions – maybe even billions – of years left to burn.

The safest star to send your wishes to? The sun! The sun is only 8 light-minutes away, and it’ll be a main-sequence star for around five billion years yet.

So when you wish upon a star, that star is less than 10,000 light-years away and will probably live for at least hundreds of thousands of years … and maybe millions or even billions of years (just like your dreams).

Laura Nicole Driessen, Postdoctoral Researcher in Radio Astronomy, University of Sydney

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Bottom line: Some cynics say that when you wish upon a star, that star is already dead. But don’t listen to them! The stars you can see, and your dreams, are perfectly safe.

The post When you wish upon a star, is it already dead? first appeared on EarthSky.

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January birthstone: The colorful garnet gemstone

The January birthstone, the garnet, comes in several types. This image shows a variety known as andradite. Image via Moha112100/ Wikimedia Commons (CC BY-SA 3.0).

If you were born in January, the garnet is your birthstone.

People often think of garnets as red gemstones. In reality, garnets come in a variety of colors. They come from around the world, and people have used them as jewelry since the Bronze Age. Most garnets mined today are not gem-quality stones. Instead, they’re used in industry, primarily as abrasives. Only those with the right size, color and clarity are cut to make splendid gemstones.

The name garnet originated from the Latin granatus, meaning seed. It may be a reference to the pomegranate, because small garnet crystals resemble the pomegranate’s red seeds.

The 2025 lunar calendars are here! Best New Year’s gifts in the universe! Check ’em out here.

Characteristics of the January birthstone

Garnets are a group of silicate minerals that occur with slightly different chemical compositions. Depending on the environment where they formed, garnet crystals may contain varying amounts of calcium, magnesium, iron, manganese, aluminum and chromium. As a result of these differences, garnets come in different colors, opacities and a hardness range of 6.0 to 7.5 on the Mohs scale.

Most garnets form when sedimentary rocks, like shales, undergo metamorphosis. That is, the rocks are structurally changed when subjected to tremendous heat and pressure. Such conditions happen where tectonic plates converge. In these conditions, minerals recrystallize into forms that are more stable in that high temperature and pressure environment. Some become garnets. To a lesser extent, garnets are also found in igneous rocks such as granite.

Because garnets are hard, they largely retain their shape when weather erodes the metamorphic and igneous rocks they crystallized in. They end up in sediment that becomes soil, sand or sedimentary rock. Miners get garnets from these formations because it’s easier to extract the crystals. Almost half of the world’s supply comes from Australia. Other major sources are India, China and the United States.

Garnets come in many colors

Garnets can come in different colors due to the presence of certain elements. Almandine has iron and aluminum, resulting in deep red, brownish-red and black crystals. Pyrope garnets are red due to magnesium and aluminum. Spessartine has manganese and aluminum that give it an orange color. Grossular contains calcium and aluminum that produces mostly green crystals but also cinnamon-brown, red and yellow. Andradite garnets are red, yellow, brown and green due to calcium and iron. Uvarovite is a rare calcium chromium garnet variety that produces bright green gems.

Garnets occur in a range of opacities, from completely opaque to transparent. Some garnets contain inclusions – tiny bits of other rocks – that reflect light to create a star-like pattern in the stone. Inclusions can also cause the gemstone to appear to change colors under different lighting conditions.

Garnets in history

People have used garnets since the Bronze Age. Archaeologists discovered red garnet jewelry in the tombs of Egyptian pharaohs dating to 3100 BCE.

Ancient Greeks and Romans also prized the gems. They wore garnet jewelry, including carved garnets on signet rings used to stamp wax seals on documents.

In Staffordshire, England, a man using a metal detector discovered a large collection of Anglo-Saxon gold and silver metalwork in 2009. Known as the Staffordshire hoard, the artifacts date to the 6th and 7th century. They include 3,500 pieces of garnet cloisonné jewelry.

Around the start of the 16th century, the discovery of garnet deposits in Bohemia (in current-day Czech Republic) set off a thriving garnet jewelry industry in Europe. The gemstone remained popular through Victorian times until interest declined at the turn of the 20th century.

A gold fitting for a weapon handle (hilt), with stone and garnet inlays, from the Staffordshire hoard. Image via portableantiquities/ Wikimedia Commons (CC BY 2.0).

Mythology behind the January birthstone

Much of the early history and mythology of garnets intertwines with other red gemstones such as rubies and spinels. Ancient jewelers were often unable to distinguish between these red gems, which they called carbuncles.

Garnets are associated with many myths. For instance, ancient warriors believed garnets brought victory. The crusaders used them as protection against wounds and accidents during their journeys. In contrast, ancient Asian warriors believed that glowing garnets, used as bullets, inflicted more severe wounds. In 1892, during hostilities on the Kashmir frontier, the Hanza tribesmen fired on British soldiers with garnet bullets, believing them more effective than lead.

As with many precious stones, people once believed garnets held medicinal powers. In medieval times, people thought garnets protected its wearer against poisons, wounds and bad dreams. They also thought they cured depression. They used red garnets to relieve fever and yellow garnets to treat jaundice.

Cut garnet gemstones. Image via Humanfeather/ Wikimedia Commons (CC BY-SA 3.0).

Learn about the birthstones for other months of the year:

January birthstone
February birthstone
March birthstone
April birthstone
May birthstone
June birthstone
July birthstone
August birthstone
September birthstone
October birthstone
November birthstone
December birthstone

Bottom line: The January birthstone is the garnet. Even though the most familiar color is red, garnets also come in yellow, green, orange, brown and black.

The post January birthstone: The colorful garnet gemstone first appeared on EarthSky.

from EarthSky https://ift.tt/YcwE3OA

The January birthstone, the garnet, comes in several types. This image shows a variety known as andradite. Image via Moha112100/ Wikimedia Commons (CC BY-SA 3.0).

If you were born in January, the garnet is your birthstone.

People often think of garnets as red gemstones. In reality, garnets come in a variety of colors. They come from around the world, and people have used them as jewelry since the Bronze Age. Most garnets mined today are not gem-quality stones. Instead, they’re used in industry, primarily as abrasives. Only those with the right size, color and clarity are cut to make splendid gemstones.

The name garnet originated from the Latin granatus, meaning seed. It may be a reference to the pomegranate, because small garnet crystals resemble the pomegranate’s red seeds.

The 2025 lunar calendars are here! Best New Year’s gifts in the universe! Check ’em out here.

Characteristics of the January birthstone

Garnets are a group of silicate minerals that occur with slightly different chemical compositions. Depending on the environment where they formed, garnet crystals may contain varying amounts of calcium, magnesium, iron, manganese, aluminum and chromium. As a result of these differences, garnets come in different colors, opacities and a hardness range of 6.0 to 7.5 on the Mohs scale.

Most garnets form when sedimentary rocks, like shales, undergo metamorphosis. That is, the rocks are structurally changed when subjected to tremendous heat and pressure. Such conditions happen where tectonic plates converge. In these conditions, minerals recrystallize into forms that are more stable in that high temperature and pressure environment. Some become garnets. To a lesser extent, garnets are also found in igneous rocks such as granite.

Because garnets are hard, they largely retain their shape when weather erodes the metamorphic and igneous rocks they crystallized in. They end up in sediment that becomes soil, sand or sedimentary rock. Miners get garnets from these formations because it’s easier to extract the crystals. Almost half of the world’s supply comes from Australia. Other major sources are India, China and the United States.

Garnets come in many colors

Garnets can come in different colors due to the presence of certain elements. Almandine has iron and aluminum, resulting in deep red, brownish-red and black crystals. Pyrope garnets are red due to magnesium and aluminum. Spessartine has manganese and aluminum that give it an orange color. Grossular contains calcium and aluminum that produces mostly green crystals but also cinnamon-brown, red and yellow. Andradite garnets are red, yellow, brown and green due to calcium and iron. Uvarovite is a rare calcium chromium garnet variety that produces bright green gems.

Garnets occur in a range of opacities, from completely opaque to transparent. Some garnets contain inclusions – tiny bits of other rocks – that reflect light to create a star-like pattern in the stone. Inclusions can also cause the gemstone to appear to change colors under different lighting conditions.

Garnets in history

People have used garnets since the Bronze Age. Archaeologists discovered red garnet jewelry in the tombs of Egyptian pharaohs dating to 3100 BCE.

Ancient Greeks and Romans also prized the gems. They wore garnet jewelry, including carved garnets on signet rings used to stamp wax seals on documents.

In Staffordshire, England, a man using a metal detector discovered a large collection of Anglo-Saxon gold and silver metalwork in 2009. Known as the Staffordshire hoard, the artifacts date to the 6th and 7th century. They include 3,500 pieces of garnet cloisonné jewelry.

Around the start of the 16th century, the discovery of garnet deposits in Bohemia (in current-day Czech Republic) set off a thriving garnet jewelry industry in Europe. The gemstone remained popular through Victorian times until interest declined at the turn of the 20th century.

A gold fitting for a weapon handle (hilt), with stone and garnet inlays, from the Staffordshire hoard. Image via portableantiquities/ Wikimedia Commons (CC BY 2.0).

Mythology behind the January birthstone

Much of the early history and mythology of garnets intertwines with other red gemstones such as rubies and spinels. Ancient jewelers were often unable to distinguish between these red gems, which they called carbuncles.

Garnets are associated with many myths. For instance, ancient warriors believed garnets brought victory. The crusaders used them as protection against wounds and accidents during their journeys. In contrast, ancient Asian warriors believed that glowing garnets, used as bullets, inflicted more severe wounds. In 1892, during hostilities on the Kashmir frontier, the Hanza tribesmen fired on British soldiers with garnet bullets, believing them more effective than lead.

As with many precious stones, people once believed garnets held medicinal powers. In medieval times, people thought garnets protected its wearer against poisons, wounds and bad dreams. They also thought they cured depression. They used red garnets to relieve fever and yellow garnets to treat jaundice.

Cut garnet gemstones. Image via Humanfeather/ Wikimedia Commons (CC BY-SA 3.0).

Learn about the birthstones for other months of the year:

January birthstone
February birthstone
March birthstone
April birthstone
May birthstone
June birthstone
July birthstone
August birthstone
September birthstone
October birthstone
November birthstone
December birthstone

Bottom line: The January birthstone is the garnet. Even though the most familiar color is red, garnets also come in yellow, green, orange, brown and black.

The post January birthstone: The colorful garnet gemstone first appeared on EarthSky.

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Why does the New Year begin on January 1?

Why do we celebrate the New Year on January 1? Find out below. Image via Mo Eid/ Pexels.

Our celebration of New Year’s Day on January 1 is a human-made creation. It’s not precisely fixed by any natural or seasonal marker. It’s a civil event, not one defined by nature. Yet, for those of us in the Northern Hemisphere – where daylight recently ebbed to its lowest point and the days are starting to get longer again – there’s a feeling of rebirth in the air. New Year’s resolutions, anyone?

The 2025 lunar calendars are here! Best New Year’s gifts in the universe! Check ’em out here.

So where does the New Year’s Day concept come from?

It stems from an ancient Roman custom, the feast of the Roman god Janus. He was the god of beginnings, gates, transitions, time, duality, doorways, passages, frames, and endings. This is also where the name for the month of January comes from, since Janus was depicted as having two opposite faces. One face looked back into the past, and the other peered forward to the future.

Likewise, on January 1, we look back at the year that just ended and forward to the new year ahead.

To celebrate the new year, the Romans also made promises to Janus. The tradition of New Year’s resolutions stems from this ancient custom. On January 1, as the year began, it was customary to exchange cheerful words of good wishes. Shortly afterwards, on January 9, the rex sacrorum – a priesthood associated with the Roman Senate – offered the sacrifice of a ram to Janus.

Learn more about Janus.

Today, although many do celebrate New Year’s Day on January 1, some cultures and religions have different new year dates.

The ancient Roman god Janus. Image via Marie-Lan Nguyen/ Wikimedia Commons (CC BY 3.0).

Rosh Hashanah: the Jewish New Year

For example, Jews use a lunar calendar and celebrate the New Year in the fall on Rosh Hashanah, the first day of the month of Tishri, which is the seventh month of the Jewish year. This date usually occurs in September, as it does in 2025. Similar to other cultures’ New Year’s Day, the two-day holiday is both a time of rejoicing and of serious introspection, a time to celebrate the completion of another year while also taking stock of one’s life and looking ahead.

Learn more about Rosh Hashanah.

Challah, a traditional Jewish bread, eaten for Rosh Hashanah. Image via Aviv Hod/ Wikimedia Commons (CC BY 3.0).

Lunar New Year

There is also the famous Chinese New Year, also known as the Lunar New Year, celebrated for weeks in January or early February. The Lunar New Year is the most important of Chinese holidays. Countries in Southeast Asia celebrate it including China, Thailand, Indonesia, Malaysia, and the Philippines. It’s also celebrated in Chinatowns and Asian homes around the world, where it’s considered a time to honor deities and ancestors and to be with family. The event always sparks a rush of travel that the New York Times has called the world’s largest annual human migration.

Last year’s Lunar New Year celebrations fell on Saturday, February 10, 2024. It was the year of the Dragon. In 2025, the Lunar New Year will begin on Saturday, January 29, 2025. It’ll be the year of the Snake.

Learn more about the Lunar New Year.

Our friend Matthew Chin in Hong Kong created this graphic and wrote: “The two Chinese characters are the same. It means ‘blessing,’ a hope that other people will get good luck. It is commonly used during Lunar New Year. The red background is also a kind of ‘good’ as Chinese people use red to represent ‘good luck.’” Thank you, Matthew!

Perihelion around January 1

By the way, in addition to the longer days here in the Northern Hemisphere, there’s another astronomical occurrence around January 1 each year that’s also related to Earth’s year, as defined by our orbit around the sun. That is, Earth’s perihelion – or closest point to the sun – happens every year in early January. In 2025, perihelion comes on January 4.

Read more about 2025’s perihelion

For 2025, the Northern Hemisphere winter stretches from December 21, 2024, to March 20, 2025. Perihelion occurs within this period, on January 4, 2025. Since Earth moves faster the closer it is to the sun, the Northern Hemisphere winter period is shorter by almost 5 days compared to the Northern Hemisphere summer, when the Earth is moving more slowly in its orbit. Chart via EarthSky.

History of New Year’s Day

January 1 hasn’t always been New Year’s Day.

In the past, some New Year’s celebrations took place at an equinox, a day when the sun is above Earth’s equator and night and day are equal in length. In many cultures, the March or vernal equinox marks a time of transition and new beginnings, and so cultural celebrations of a new year were natural for that equinox.

The September or autumnal equinox also had its proponents for the beginning of a new year. For example, the French Republican calendar – implemented during the French Revolution and used for about 12 years from late 1793 to 1805 – started its year at the September equinox.

The Greeks celebrated the new year on the winter solstice, the shortest day of the year.

Happy 2025, everyone!

Bottom line: We celebrate New Year’s Day on January 1 by tradition. Our modern New Year’s Day celebration stems from the ancient two-faced Roman god Janus, after whom the month of January is named.

The post Why does the New Year begin on January 1? first appeared on EarthSky.

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Why do we celebrate the New Year on January 1? Find out below. Image via Mo Eid/ Pexels.

Our celebration of New Year’s Day on January 1 is a human-made creation. It’s not precisely fixed by any natural or seasonal marker. It’s a civil event, not one defined by nature. Yet, for those of us in the Northern Hemisphere – where daylight recently ebbed to its lowest point and the days are starting to get longer again – there’s a feeling of rebirth in the air. New Year’s resolutions, anyone?

The 2025 lunar calendars are here! Best New Year’s gifts in the universe! Check ’em out here.

So where does the New Year’s Day concept come from?

It stems from an ancient Roman custom, the feast of the Roman god Janus. He was the god of beginnings, gates, transitions, time, duality, doorways, passages, frames, and endings. This is also where the name for the month of January comes from, since Janus was depicted as having two opposite faces. One face looked back into the past, and the other peered forward to the future.

Likewise, on January 1, we look back at the year that just ended and forward to the new year ahead.

To celebrate the new year, the Romans also made promises to Janus. The tradition of New Year’s resolutions stems from this ancient custom. On January 1, as the year began, it was customary to exchange cheerful words of good wishes. Shortly afterwards, on January 9, the rex sacrorum – a priesthood associated with the Roman Senate – offered the sacrifice of a ram to Janus.

Learn more about Janus.

Today, although many do celebrate New Year’s Day on January 1, some cultures and religions have different new year dates.

The ancient Roman god Janus. Image via Marie-Lan Nguyen/ Wikimedia Commons (CC BY 3.0).

Rosh Hashanah: the Jewish New Year

For example, Jews use a lunar calendar and celebrate the New Year in the fall on Rosh Hashanah, the first day of the month of Tishri, which is the seventh month of the Jewish year. This date usually occurs in September, as it does in 2025. Similar to other cultures’ New Year’s Day, the two-day holiday is both a time of rejoicing and of serious introspection, a time to celebrate the completion of another year while also taking stock of one’s life and looking ahead.

Learn more about Rosh Hashanah.

Challah, a traditional Jewish bread, eaten for Rosh Hashanah. Image via Aviv Hod/ Wikimedia Commons (CC BY 3.0).

Lunar New Year

There is also the famous Chinese New Year, also known as the Lunar New Year, celebrated for weeks in January or early February. The Lunar New Year is the most important of Chinese holidays. Countries in Southeast Asia celebrate it including China, Thailand, Indonesia, Malaysia, and the Philippines. It’s also celebrated in Chinatowns and Asian homes around the world, where it’s considered a time to honor deities and ancestors and to be with family. The event always sparks a rush of travel that the New York Times has called the world’s largest annual human migration.

Last year’s Lunar New Year celebrations fell on Saturday, February 10, 2024. It was the year of the Dragon. In 2025, the Lunar New Year will begin on Saturday, January 29, 2025. It’ll be the year of the Snake.

Learn more about the Lunar New Year.

Our friend Matthew Chin in Hong Kong created this graphic and wrote: “The two Chinese characters are the same. It means ‘blessing,’ a hope that other people will get good luck. It is commonly used during Lunar New Year. The red background is also a kind of ‘good’ as Chinese people use red to represent ‘good luck.’” Thank you, Matthew!

Perihelion around January 1

By the way, in addition to the longer days here in the Northern Hemisphere, there’s another astronomical occurrence around January 1 each year that’s also related to Earth’s year, as defined by our orbit around the sun. That is, Earth’s perihelion – or closest point to the sun – happens every year in early January. In 2025, perihelion comes on January 4.

Read more about 2025’s perihelion

For 2025, the Northern Hemisphere winter stretches from December 21, 2024, to March 20, 2025. Perihelion occurs within this period, on January 4, 2025. Since Earth moves faster the closer it is to the sun, the Northern Hemisphere winter period is shorter by almost 5 days compared to the Northern Hemisphere summer, when the Earth is moving more slowly in its orbit. Chart via EarthSky.

History of New Year’s Day

January 1 hasn’t always been New Year’s Day.

In the past, some New Year’s celebrations took place at an equinox, a day when the sun is above Earth’s equator and night and day are equal in length. In many cultures, the March or vernal equinox marks a time of transition and new beginnings, and so cultural celebrations of a new year were natural for that equinox.

The September or autumnal equinox also had its proponents for the beginning of a new year. For example, the French Republican calendar – implemented during the French Revolution and used for about 12 years from late 1793 to 1805 – started its year at the September equinox.

The Greeks celebrated the new year on the winter solstice, the shortest day of the year.

Happy 2025, everyone!

Bottom line: We celebrate New Year’s Day on January 1 by tradition. Our modern New Year’s Day celebration stems from the ancient two-faced Roman god Janus, after whom the month of January is named.

The post Why does the New Year begin on January 1? first appeared on EarthSky.

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Mars starts a new year: avalanches, icy explosions and dunes

• Spring on Mars brings explosive changes. As temperatures rise, the Martian northern hemisphere experiences dramatic events such as frost avalanches, carbon dioxide gas geysers, and winds reshaping polar ice caps and dunes.
• Unlike Earth, Mars’ ice sublimates directly into gas. The sublimation causes explosive activity like “spiders” (scour marks left after ice sublimation) and dark fans of material from gas geysers.
• The Mars Reconnaissance Orbiter has been crucial for studying these dynamic processes for nearly 20 years. It captures unprecedented images and insights into the red planet’s surface evolution.

NASA/JPL published this original article on December 20, 2024. Edits by EarthSky.

Mars is beginning another 687-day-long year

While we’re celebrating New Year’s Eve here on Earth, Mars scientists are ahead of the game: The red planet completed a trip around the sun on November 12, 2024, prompting a few researchers to raise a toast.

But the Martian year, which is 687 Earth days, ends in a very different way in the planet’s northern hemisphere than it does in Earth’s northern hemisphere. While winter’s kicking in here, spring is starting there. That means temperatures are rising and ice is thinning, leading to frost avalanches crashing down cliffsides, carbon dioxide gas exploding from the ground and powerful winds helping reshape the north pole.

Serina Diniega, who studies planetary surfaces at NASA’s Jet Propulsion Laboratory in Southern California, said:

Springtime on Earth has lots of trickling as water ice gradually melts. But on Mars, everything happens with a bang.

The 2025 EarthSky Lunar Calendar is now available! A unique and beautiful poster-sized calendar. Get yours today!

Springtime literally explodes on the red planet

Mars’ wispy atmosphere doesn’t allow liquids to pool on the surface as on Earth. Instead of melting, ice sublimates, turning directly into a gas. The sudden transition in spring means a lot of violent changes as both water ice and carbon dioxide ice – dry ice, which is much more plentiful on Mars than frozen water – weaken and break.

Diniega said:

You get lots of cracks and explosions instead of melting. I imagine it gets really noisy.

Using the cameras and other sensors aboard NASA’s Mars Reconnaissance Orbiter (MRO), which launched in 2005, scientists study all this activity to improve their understanding of the forces shaping the dynamic Martian surface. Here’s some of what they track.

Martian spring involves lots of cracking ice, which led to this 66-foot-wide (20-meter-wide) chunk of carbon dioxide frost captured in freefall by the HiRISE camera aboard NASA’s Mars Reconnaissance Orbiter (MRO) in 2015. Image via NASA/ JPL-Caltech/ University of Arizona.

Frost avalanches caught in action on Mars

In 2015, MRO’s High-Resolution Imaging Science Experiment (HiRISE) camera captured a 66-foot-wide (20-meter-wide) chunk of carbon dioxide frost in freefall. Chance observations like this are reminders of just how different Mars is from Earth, Diniega said, especially in springtime, when these surface changes are most noticeable.

Diniega said:

We’re lucky we’ve had a spacecraft like MRO observing Mars for as long as it has. Watching for almost 20 years has let us catch dramatic moments like these avalanches.

As light shines through carbon dioxide ice on Mars, it heats up its bottom layers, which, rather than melting into a liquid, turn into gas. The builtup gas eventually results in explosive geysers that toss dark fans of debris onto the surface. Image via NASA/ JPL-Caltech/ University of Arizona.

Gas geysers blast ‘spiders’ on Martian southern hemisphere

Diniega has relied on HiRISE to study another quirk of Martian springtime: gas geysers that blast out of the surface, throwing out dark fans of sand and dust. These explosive jets form due to energetic sublimation of carbon dioxide ice. As sunlight shines through the ice, its bottom layers turn to gas, building pressure until it bursts into the air, creating those dark fans of material.

But to see the best examples of the newest fans, researchers will have to wait until December 2025, when spring starts in the southern hemisphere. There, the fans are bigger and more clearly defined.

Another difference between ice-related action in the two hemispheres: Once all the ice around some northern geysers has sublimated in summer, what’s left behind in the dirt are scour marks that, from space, look like giant spider legs. Researchers recently re-created this process in a JPL lab.

Sometimes, after carbon dioxide geysers have erupted from ice-covered areas on Mars, they leave scour marks on the surface. When the ice is all gone by summer, these long scour marks look like the legs of giant spiders. Image via NASA/ JPL-Caltech/ University of Arizona.

Powerful winds leave enormous scars on Mars’ ice cap

For Isaac Smith of Toronto’s York University, one of the most fascinating subjects in springtime is the Texas-size ice cap at Mars’ north pole. Etched into the icy dome are swirling troughs, revealing traces of the red surface below. The effect is like a swirl of milk in a café latte.

Noting that some are as long as California, Smith said:

These things are enormous. You can find similar troughs in Antarctica but nothing at this scale.

Fast, warm wind has carved the spiral shapes over eons, and the troughs act as channels for springtime wind gusts that become more powerful as ice at the north pole starts to thaw. Just like the Santa Ana winds in Southern California or the Chinook winds in the Rocky Mountains, these gusts pick up speed and temperature as they ride down the troughs, in what’s called an adiabatic process.

As temperatures rise, powerful winds kick up that carve deep troughs into the ice cap of Mars’ north pole. Some of these troughs are as long as California. And they give the Martian north pole its trademark swirls. NASA’s now-inactive Mars Global Surveyor captured this image. Image via NASA/ JPL-Caltech/ MSSS.

Sand dunes wander across the Martian landscape

The winds that carve the north pole’s troughs also reshape Mars’ sand dunes, causing sand to pile up on one side while removing sand from the other side. Over time, the process causes dunes to migrate, just as it does with dunes on Earth.

Last September, Smith coauthored a paper detailing how carbon dioxide frost settles on top of polar sand dunes during winter, freezing them in place. When the frost all thaws away in the spring, the dunes begin migrating again.

Each northern spring is a little different, with variations leading to ice sublimating faster or slower, controlling the pace of all these phenomena on the surface. And these strange phenomena are just part of the seasonal changes on Mars: the southern hemisphere has its own unique activity.

Surrounded by frost, these Martian dunes are in Mars’ northern hemisphere. NASA’s Mars Reconnaissance Orbiter used its HiRISE camera to capture them from above on September 8, 2022. Image via NASA/ JPL-Caltech/ University of Arizona.

Bottom line: A new and explosive year began on Mars on November 14, 2024. NASA and its partners are tracking the season’s strange and unique features.

Read more: Mars is racing toward opposition in January 2025: Start watching now!

The post Mars starts a new year: avalanches, icy explosions and dunes first appeared on EarthSky.

from EarthSky https://ift.tt/Xye6Sjp

• Spring on Mars brings explosive changes. As temperatures rise, the Martian northern hemisphere experiences dramatic events such as frost avalanches, carbon dioxide gas geysers, and winds reshaping polar ice caps and dunes.
• Unlike Earth, Mars’ ice sublimates directly into gas. The sublimation causes explosive activity like “spiders” (scour marks left after ice sublimation) and dark fans of material from gas geysers.
• The Mars Reconnaissance Orbiter has been crucial for studying these dynamic processes for nearly 20 years. It captures unprecedented images and insights into the red planet’s surface evolution.

NASA/JPL published this original article on December 20, 2024. Edits by EarthSky.

Mars is beginning another 687-day-long year

While we’re celebrating New Year’s Eve here on Earth, Mars scientists are ahead of the game: The red planet completed a trip around the sun on November 12, 2024, prompting a few researchers to raise a toast.

But the Martian year, which is 687 Earth days, ends in a very different way in the planet’s northern hemisphere than it does in Earth’s northern hemisphere. While winter’s kicking in here, spring is starting there. That means temperatures are rising and ice is thinning, leading to frost avalanches crashing down cliffsides, carbon dioxide gas exploding from the ground and powerful winds helping reshape the north pole.

Serina Diniega, who studies planetary surfaces at NASA’s Jet Propulsion Laboratory in Southern California, said:

Springtime on Earth has lots of trickling as water ice gradually melts. But on Mars, everything happens with a bang.

The 2025 EarthSky Lunar Calendar is now available! A unique and beautiful poster-sized calendar. Get yours today!

Springtime literally explodes on the red planet

Mars’ wispy atmosphere doesn’t allow liquids to pool on the surface as on Earth. Instead of melting, ice sublimates, turning directly into a gas. The sudden transition in spring means a lot of violent changes as both water ice and carbon dioxide ice – dry ice, which is much more plentiful on Mars than frozen water – weaken and break.

Diniega said:

You get lots of cracks and explosions instead of melting. I imagine it gets really noisy.

Using the cameras and other sensors aboard NASA’s Mars Reconnaissance Orbiter (MRO), which launched in 2005, scientists study all this activity to improve their understanding of the forces shaping the dynamic Martian surface. Here’s some of what they track.

Martian spring involves lots of cracking ice, which led to this 66-foot-wide (20-meter-wide) chunk of carbon dioxide frost captured in freefall by the HiRISE camera aboard NASA’s Mars Reconnaissance Orbiter (MRO) in 2015. Image via NASA/ JPL-Caltech/ University of Arizona.

Frost avalanches caught in action on Mars

In 2015, MRO’s High-Resolution Imaging Science Experiment (HiRISE) camera captured a 66-foot-wide (20-meter-wide) chunk of carbon dioxide frost in freefall. Chance observations like this are reminders of just how different Mars is from Earth, Diniega said, especially in springtime, when these surface changes are most noticeable.

Diniega said:

We’re lucky we’ve had a spacecraft like MRO observing Mars for as long as it has. Watching for almost 20 years has let us catch dramatic moments like these avalanches.

As light shines through carbon dioxide ice on Mars, it heats up its bottom layers, which, rather than melting into a liquid, turn into gas. The builtup gas eventually results in explosive geysers that toss dark fans of debris onto the surface. Image via NASA/ JPL-Caltech/ University of Arizona.

Gas geysers blast ‘spiders’ on Martian southern hemisphere

Diniega has relied on HiRISE to study another quirk of Martian springtime: gas geysers that blast out of the surface, throwing out dark fans of sand and dust. These explosive jets form due to energetic sublimation of carbon dioxide ice. As sunlight shines through the ice, its bottom layers turn to gas, building pressure until it bursts into the air, creating those dark fans of material.

But to see the best examples of the newest fans, researchers will have to wait until December 2025, when spring starts in the southern hemisphere. There, the fans are bigger and more clearly defined.

Another difference between ice-related action in the two hemispheres: Once all the ice around some northern geysers has sublimated in summer, what’s left behind in the dirt are scour marks that, from space, look like giant spider legs. Researchers recently re-created this process in a JPL lab.

Sometimes, after carbon dioxide geysers have erupted from ice-covered areas on Mars, they leave scour marks on the surface. When the ice is all gone by summer, these long scour marks look like the legs of giant spiders. Image via NASA/ JPL-Caltech/ University of Arizona.

Powerful winds leave enormous scars on Mars’ ice cap

For Isaac Smith of Toronto’s York University, one of the most fascinating subjects in springtime is the Texas-size ice cap at Mars’ north pole. Etched into the icy dome are swirling troughs, revealing traces of the red surface below. The effect is like a swirl of milk in a café latte.

Noting that some are as long as California, Smith said:

These things are enormous. You can find similar troughs in Antarctica but nothing at this scale.

Fast, warm wind has carved the spiral shapes over eons, and the troughs act as channels for springtime wind gusts that become more powerful as ice at the north pole starts to thaw. Just like the Santa Ana winds in Southern California or the Chinook winds in the Rocky Mountains, these gusts pick up speed and temperature as they ride down the troughs, in what’s called an adiabatic process.

As temperatures rise, powerful winds kick up that carve deep troughs into the ice cap of Mars’ north pole. Some of these troughs are as long as California. And they give the Martian north pole its trademark swirls. NASA’s now-inactive Mars Global Surveyor captured this image. Image via NASA/ JPL-Caltech/ MSSS.

Sand dunes wander across the Martian landscape

The winds that carve the north pole’s troughs also reshape Mars’ sand dunes, causing sand to pile up on one side while removing sand from the other side. Over time, the process causes dunes to migrate, just as it does with dunes on Earth.

Last September, Smith coauthored a paper detailing how carbon dioxide frost settles on top of polar sand dunes during winter, freezing them in place. When the frost all thaws away in the spring, the dunes begin migrating again.

Each northern spring is a little different, with variations leading to ice sublimating faster or slower, controlling the pace of all these phenomena on the surface. And these strange phenomena are just part of the seasonal changes on Mars: the southern hemisphere has its own unique activity.

Surrounded by frost, these Martian dunes are in Mars’ northern hemisphere. NASA’s Mars Reconnaissance Orbiter used its HiRISE camera to capture them from above on September 8, 2022. Image via NASA/ JPL-Caltech/ University of Arizona.

Bottom line: A new and explosive year began on Mars on November 14, 2024. NASA and its partners are tracking the season’s strange and unique features.

Read more: Mars is racing toward opposition in January 2025: Start watching now!

The post Mars starts a new year: avalanches, icy explosions and dunes first appeared on EarthSky.

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Black Moon coming on December 30-31

View at EarthSky Community Photos. | Chuck Reinhart captured this starry scene from Vincennes, Indiana, on November 1, 2024. Thank you, Chuck! On December 30-31, 2024, we’ll have what some call a Black Moon. On that evening, the moon won’t be visible because it’s a new moon, the 2nd new moon of a month: voila! A Black Moon.

The 2025 EarthSky Lunar Calendar is now available! Keep up with the moon’s phases. Get yours today!

What’s a Black Moon?

You’ve probably already heard of a Blue Moon. There are two Blue Moon definitions, but the most common one is when we have two full moons in one calendar month. In that case, the 2nd one is a Blue Moon. Now here’s another moon name that has emerged in recent years. It comes when we have two new moons in a month. Then the 2nd one gets the label Black Moon. And on December 30-31, 2024, we have a 2nd new moon of the month, a Black Moon just as 2024 is drawing to a close.

The moment of new moon is at 4:26 p.m. CST (22:26 UTC) on December 30, 2024. So it falls on December 30 for the Americas and December 31 for Europe, Africa and Asia.

A Black Moon – like any new moon – isn’t visible in Earth’s sky. The moon is new when it’s more or less between the Earth and sun for that monthly orbit. So, at every new moon, the moon travels close in our sky to the sun. For all of Earth, it’s up in daylight and can’t be seen. But new-moon-time is a great time to stargaze, because without the moon in the sky, the night is darker, and you can see more stars. This is especially true if you venture out to a dark-sky site.

Another definition of Black Moon

Just like there are two definitions for a Blue Moon (the 2nd full moon in a calendar month or the 3rd full moon in a season with four full moons), there are technically two definitions for Black Moon, too. This month’s Black Moon is the 2nd in a calendar month. But there’s also a seasonal Black Moon, which is the 3rd new moon in a season with four new moons.

Black Moons as the 2nd of two in a calendar month are the most common sort. According to TimeandDate.com, they happen about once every 29 months. A seasonal Black Moon is a bit more rare, occurring about once every 33 months.

The last seasonal Black Moon was in May 2023. And the next seasonal Black Moon is on August 23, 2025. The last monthly Black Moon was in April 2022. And the next monthly Black Moon (after December) is on August 31, 2027.

The name Blue Moon can be misleading. The moon doesn’t appear blue in color during these full moons. But the name Black Moon is slightly more accurate, because you can’t see the moon in the night sky (because it’s up in the daytime!). Also, if you think about the body of the moon itself … its darkened half is facing Earth at the time of new moon.

A Black Moon really does appear dark from Earth. Its darkened half is facing Earth at that time. But you can’t see a Black Moon. Like any new moon, it travels across the sky with the sun during the day, hidden in the sun’s glare. Image via TimeandDate.com. Used with permission.

Which planets will you see on the night of the Black Moon?

Late December 2024 – and January 2025 – are a great time to see planets and stars! Thanks for the dark sky, Black Moon! If you go out to stargaze on December 30-31 – the night of the Black Moon or new moon – what will you see? If you head to a dark-sky site, the answer is a lot! The velvety black night sky will be punctuated with bright planets and stars.

If you head out just after sunset (that’s just after sunset no matter where you are on Earth), look toward the western horizon to see the brightest planet, Venus. Because Venus is so bright and near the horizon, it’s often mistaken for a plane … or maybe a “hovering” drone? Not too far above Venus in the western sky is Saturn; it’s fainter, but might look golden in color. Then turn around and look high in the east. No matter where you are on Earth, you’ll see another bright point of light, mighty Jupiter, the 2nd-brightest light in our night sky right now. Wait a bit. The planet Mars – now very bright, too, and red in color – will ascend over your eastern horizon not long after true darkness falls.

On the evening of December 30 to 31, 2024, during the Black Moon, 4 planets will shine in the dark sky. Venus is by far the brightest. Image via EarthSky.

Stars during the Black Moon

So there are four bright planets in the evening sky now! But December and January are also a great time to see many bright stars. At thius time of year, we’re looking opposite the center of our Milky Way galaxy. But we’re looking into the spiral arm of the galaxy in which our sun resides. The many bright stars in the evening sky now also belong to this spiral arm, called the Orion Arm.

Many of the brightest you’ll see on a late December or early January evening trace out a pattern known as the Winter Circle or Hexagon. This circular pattern of 1st-magnitude stars are from six different constellations: Rigel in Orion the Hunter, Aldebaran in Taurus the Bull, Capella in Auriga the Charioteer, Pollux (and its forever companion Castor) in Gemini the Twins, Procyon in Canis Minor the Lesser Dog and Sirius in Canis Major the Greater Dog. Also, an additional 1st-magnitude star, Betelgeuse in Orion the Hunter, lies toward the center of the Circle.

Plus, on the evening of the Black Moon – December 30-31 – both Jupiter and Mars are among the stars of the Winter Circle.

On the evening of the Black Moon from December 30-31, 2024, Jupiter and Mars will be among the stars of the Winter Circle. Image via EarthSky.

And meteors!

On December 30-31, we’re just days away from the peak of the Quadrantid meteor shower, on January 2-3, 2025. This meteor shower favors those in the Northern Hemisphere, because the radiant point is near the Big Dipper asterism. So don’t be surprised if you see meteors under the Black Moon!

The radiant point for the Quadrantid meteor shower is far to the north in Earth’s sky, so the shower is best seen from Earth’s Northern Hemisphere. From mid-northern latitudes, the radiant point for the Quadrantid meteor shower climbs over the horizon after midnight and is highest in the sky before dawn.

Bottom line: We’ll have a Black Moon – the second new moon in a calendar month – overnight from December 30 to 31, 2024. Here’s what you’ll see that night.

The post Black Moon coming on December 30-31 first appeared on EarthSky.

from EarthSky https://ift.tt/mQjv6CG

View at EarthSky Community Photos. | Chuck Reinhart captured this starry scene from Vincennes, Indiana, on November 1, 2024. Thank you, Chuck! On December 30-31, 2024, we’ll have what some call a Black Moon. On that evening, the moon won’t be visible because it’s a new moon, the 2nd new moon of a month: voila! A Black Moon.

The 2025 EarthSky Lunar Calendar is now available! Keep up with the moon’s phases. Get yours today!

What’s a Black Moon?

You’ve probably already heard of a Blue Moon. There are two Blue Moon definitions, but the most common one is when we have two full moons in one calendar month. In that case, the 2nd one is a Blue Moon. Now here’s another moon name that has emerged in recent years. It comes when we have two new moons in a month. Then the 2nd one gets the label Black Moon. And on December 30-31, 2024, we have a 2nd new moon of the month, a Black Moon just as 2024 is drawing to a close.

The moment of new moon is at 4:26 p.m. CST (22:26 UTC) on December 30, 2024. So it falls on December 30 for the Americas and December 31 for Europe, Africa and Asia.

A Black Moon – like any new moon – isn’t visible in Earth’s sky. The moon is new when it’s more or less between the Earth and sun for that monthly orbit. So, at every new moon, the moon travels close in our sky to the sun. For all of Earth, it’s up in daylight and can’t be seen. But new-moon-time is a great time to stargaze, because without the moon in the sky, the night is darker, and you can see more stars. This is especially true if you venture out to a dark-sky site.

Another definition of Black Moon

Just like there are two definitions for a Blue Moon (the 2nd full moon in a calendar month or the 3rd full moon in a season with four full moons), there are technically two definitions for Black Moon, too. This month’s Black Moon is the 2nd in a calendar month. But there’s also a seasonal Black Moon, which is the 3rd new moon in a season with four new moons.

Black Moons as the 2nd of two in a calendar month are the most common sort. According to TimeandDate.com, they happen about once every 29 months. A seasonal Black Moon is a bit more rare, occurring about once every 33 months.

The last seasonal Black Moon was in May 2023. And the next seasonal Black Moon is on August 23, 2025. The last monthly Black Moon was in April 2022. And the next monthly Black Moon (after December) is on August 31, 2027.

The name Blue Moon can be misleading. The moon doesn’t appear blue in color during these full moons. But the name Black Moon is slightly more accurate, because you can’t see the moon in the night sky (because it’s up in the daytime!). Also, if you think about the body of the moon itself … its darkened half is facing Earth at the time of new moon.

A Black Moon really does appear dark from Earth. Its darkened half is facing Earth at that time. But you can’t see a Black Moon. Like any new moon, it travels across the sky with the sun during the day, hidden in the sun’s glare. Image via TimeandDate.com. Used with permission.

Which planets will you see on the night of the Black Moon?

Late December 2024 – and January 2025 – are a great time to see planets and stars! Thanks for the dark sky, Black Moon! If you go out to stargaze on December 30-31 – the night of the Black Moon or new moon – what will you see? If you head to a dark-sky site, the answer is a lot! The velvety black night sky will be punctuated with bright planets and stars.

If you head out just after sunset (that’s just after sunset no matter where you are on Earth), look toward the western horizon to see the brightest planet, Venus. Because Venus is so bright and near the horizon, it’s often mistaken for a plane … or maybe a “hovering” drone? Not too far above Venus in the western sky is Saturn; it’s fainter, but might look golden in color. Then turn around and look high in the east. No matter where you are on Earth, you’ll see another bright point of light, mighty Jupiter, the 2nd-brightest light in our night sky right now. Wait a bit. The planet Mars – now very bright, too, and red in color – will ascend over your eastern horizon not long after true darkness falls.

On the evening of December 30 to 31, 2024, during the Black Moon, 4 planets will shine in the dark sky. Venus is by far the brightest. Image via EarthSky.

Stars during the Black Moon

So there are four bright planets in the evening sky now! But December and January are also a great time to see many bright stars. At thius time of year, we’re looking opposite the center of our Milky Way galaxy. But we’re looking into the spiral arm of the galaxy in which our sun resides. The many bright stars in the evening sky now also belong to this spiral arm, called the Orion Arm.

Many of the brightest you’ll see on a late December or early January evening trace out a pattern known as the Winter Circle or Hexagon. This circular pattern of 1st-magnitude stars are from six different constellations: Rigel in Orion the Hunter, Aldebaran in Taurus the Bull, Capella in Auriga the Charioteer, Pollux (and its forever companion Castor) in Gemini the Twins, Procyon in Canis Minor the Lesser Dog and Sirius in Canis Major the Greater Dog. Also, an additional 1st-magnitude star, Betelgeuse in Orion the Hunter, lies toward the center of the Circle.

Plus, on the evening of the Black Moon – December 30-31 – both Jupiter and Mars are among the stars of the Winter Circle.

On the evening of the Black Moon from December 30-31, 2024, Jupiter and Mars will be among the stars of the Winter Circle. Image via EarthSky.

And meteors!

On December 30-31, we’re just days away from the peak of the Quadrantid meteor shower, on January 2-3, 2025. This meteor shower favors those in the Northern Hemisphere, because the radiant point is near the Big Dipper asterism. So don’t be surprised if you see meteors under the Black Moon!

The radiant point for the Quadrantid meteor shower is far to the north in Earth’s sky, so the shower is best seen from Earth’s Northern Hemisphere. From mid-northern latitudes, the radiant point for the Quadrantid meteor shower climbs over the horizon after midnight and is highest in the sky before dawn.

Bottom line: We’ll have a Black Moon – the second new moon in a calendar month – overnight from December 30 to 31, 2024. Here’s what you’ll see that night.

The post Black Moon coming on December 30-31 first appeared on EarthSky.

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