March equinox 2026: Here’s all you need to know

Satellite views of Earth on the solstices and equinoxes. We are at the March equinox now. Read more about this image. Images via NASA Earth Observatory.

The March equinox has arrived! Here’s all you need to know about it.

What is it? The March equinox – aka the vernal equinox – marks the sun’s crossing above Earth’s equator, moving from south to north. Earth’s tilt on its axis is what causes this northward shift of the sun’s path across our sky at this time of year. Earth’s tilt is now bringing spring and summer to the Northern Hemisphere. At the same time, the March equinox marks the beginning of autumn – and a shift toward winter – in the Southern Hemisphere.
When is it? The sun crosses the celestial equator – a line directly above Earth’s equator – at 14:46 UTC on March 20, 2026 (9:46 a.m. CDT).

No matter where you are on Earth, the equinox brings us a number of seasonal effects, noticeable to nature lovers around the globe.

Equal day and night on the equinox?

At the equinox, Earth’s two hemispheres are receiving the sun’s rays equally. Night and day are often said to be equal in length. In fact, the word equinox comes from the Latin aequus (equal) and nox (night). For our ancestors, whose timekeeping was less precise than ours, day and night likely did seem equal. But today we know it’s not exactly so.

Read more: Are day and night equal at the equinox?

Fastest sunsets at the equinoxes

The fastest sunsets and sunrises of the year happen at the equinoxes. We’re talking here about the length of time it takes for the whole sun to sink below the horizon.

Read more: Fastest sunsets happen near equinoxes

View at EarthSky Community Photos. | Iaroslav Kourzenkov of Halifax, Nova Scotia, Canada, captured this image of the sunset on the equinox on March 20, 2023. Thank you, Iaroslav!

Sun rises due east and sets due west?

Here’s another equinox phenomenon. You might hear that the sun rises due east and sets due west at the equinox. Is that true? Yes it is. In fact, it’s the case no matter where you live on Earth, with the exception of the North and South Poles. At the equinoxes, the sun appears overhead at noon as seen from Earth’s equator, as the illustration below shows. This illustration shows the sun’s location on the celestial equator, every hour, on the day of the equinox.

No matter where you are on Earth – except at the Earth’s North and South Poles – you have a due east and due west point on your horizon. That point marks the intersection of your horizon with the celestial equator: the imaginary line above the true equator of the Earth.

The sun is on the celestial equator, and the celestial equator intersects all of our horizons at points due east and due west. Voila! The sun rises due east and sets due west.

Read more: Sun rises due east and sets due west

The day arc of the sun, every hour, at the equinox, as seen on the (imaginary) celestial sphere surrounding Earth. At the equinox, the sun is directly above Earth’s equator. Image via Tau’olunga/ Wikimedia Commons (CC BY-SA 2.5).

More March equinox effects

And there are also plenty more effects in play around the time of the March equinox that all of us can notice. In the Northern Hemisphere, the March equinox brings earlier sunrises, later sunsets and sprouting plants.

Meanwhile, you’ll find the opposite season – later sunrises, earlier sunsets, chillier winds, dry and falling leaves – south of the equator.

The equinoxes and solstices are caused by Earth’s tilt on its axis and ceaseless motion in orbit. You can think of an equinox as happening on the imaginary dome of our sky, or as an event that happens in Earth’s orbit around the sun.

The Earth-centered view

If you think of it from an Earth-centered perspective, you can think of the celestial equator as a great circle dividing Earth’s sky into its Northern and Southern Hemispheres. The celestial equator is an imaginary line wrapping the sky directly above Earth’s equator. At the equinox, the sun crosses the celestial equator to enter the sky’s Northern Hemisphere.

The day arc of the equinox sun as seen from Earth’s equator. Also showing are twilight suns (in red) down to -18 degrees altitude. Note that the sun is at its highest point at noon. And see that the tree’s shadow at noon is cast straight down. That is – as seen from the equator on the day of an equinox – a tree stands in the center of its own shadow. Image via Tau’olunga/ Wikimedia Commons (CC BY-SA 2.5).

The Earth-in-space view

If you think of it from an Earth-in-space perspective, you have to think of Earth in orbit around the sun. And we all know Earth doesn’t orbit upright but is instead tilted on its axis by 23 1/2 degrees. So Earth’s Northern and Southern Hemispheres trade places in receiving the sun’s light and warmth most directly. We have an equinox twice a year – spring and fall – when the tilt of the Earth’s axis and Earth’s orbit around the sun combine in such a way that the axis is inclined neither away from nor toward the sun.

Here are satellite views of Earth on the solstices and equinoxes, via NASA Earth Observatory.

Things change fast around the equinoxes

Since Earth never stops moving around the sun, the position of the sunrise and sunset – and the days of approximately equal sunlight and night – will change quickly.

The video below was the Astronomy Picture of the Day for March 19, 2014. APOD explained:

At an equinox, the Earth’s terminator – the dividing line between day and night – becomes vertical and connects the North and South Poles. The time-lapse video [above] demonstrates this by displaying an entire year on planet Earth in 12 seconds. From geosynchronous orbit, the Meteosat satellite recorded these infrared images of the Earth every day at the same local time. The video started at the September 2010 equinox with the terminator line being vertical.

As the Earth revolved around the sun, the terminator was seen to tilt in a way that provides less daily sunlight to the Northern Hemisphere, causing winter in the north. As the year progressed, the March 2011 equinox arrived halfway through the video, followed by the terminator tilting the other way, causing winter in the Southern Hemisphere and summer in the north. The captured year ends again with the September equinox, concluding another of billions of trips the Earth has taken – and will take – around the sun.

The equinox is an event that takes place in Earth’s orbit around the sun. Image via National Weather Service/ weather.gov.

Where are signs of the March equinox in nature?

Everywhere! Forget about the weather for a moment, and think only about daylight. In terms of daylight, the knowledge that spring is here – and summer is coming – permeates all of nature on the northern half of Earth’s globe.

Notice the arc of the sun across the sky each day. You’ll find that it’s shifting toward the north. Responding to the change in daylight, birds and butterflies are migrating back northward, too, along with the path of the sun.

The longer days do bring with them warmer weather. People are leaving their winter coats at home. Trees are budding, and plants are beginning a new cycle of growth. In many places, spring flowers are beginning to bloom.

Meanwhile, in the Southern Hemisphere, the days are getting shorter and nights longer. A chill is in the air. Fall is here, and winter is coming!

Bottom line: Happy equinox! The 2026 March equinox falls March 20 at 14:46 UTC. All you need to know about the March equinox here.

The post March equinox 2026: Here’s all you need to know first appeared on EarthSky.

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Satellite views of Earth on the solstices and equinoxes. We are at the March equinox now. Read more about this image. Images via NASA Earth Observatory.

The March equinox has arrived! Here’s all you need to know about it.

What is it? The March equinox – aka the vernal equinox – marks the sun’s crossing above Earth’s equator, moving from south to north. Earth’s tilt on its axis is what causes this northward shift of the sun’s path across our sky at this time of year. Earth’s tilt is now bringing spring and summer to the Northern Hemisphere. At the same time, the March equinox marks the beginning of autumn – and a shift toward winter – in the Southern Hemisphere.
When is it? The sun crosses the celestial equator – a line directly above Earth’s equator – at 14:46 UTC on March 20, 2026 (9:46 a.m. CDT).

No matter where you are on Earth, the equinox brings us a number of seasonal effects, noticeable to nature lovers around the globe.

Equal day and night on the equinox?

At the equinox, Earth’s two hemispheres are receiving the sun’s rays equally. Night and day are often said to be equal in length. In fact, the word equinox comes from the Latin aequus (equal) and nox (night). For our ancestors, whose timekeeping was less precise than ours, day and night likely did seem equal. But today we know it’s not exactly so.

Read more: Are day and night equal at the equinox?

Fastest sunsets at the equinoxes

The fastest sunsets and sunrises of the year happen at the equinoxes. We’re talking here about the length of time it takes for the whole sun to sink below the horizon.

Read more: Fastest sunsets happen near equinoxes

View at EarthSky Community Photos. | Iaroslav Kourzenkov of Halifax, Nova Scotia, Canada, captured this image of the sunset on the equinox on March 20, 2023. Thank you, Iaroslav!

Sun rises due east and sets due west?

Here’s another equinox phenomenon. You might hear that the sun rises due east and sets due west at the equinox. Is that true? Yes it is. In fact, it’s the case no matter where you live on Earth, with the exception of the North and South Poles. At the equinoxes, the sun appears overhead at noon as seen from Earth’s equator, as the illustration below shows. This illustration shows the sun’s location on the celestial equator, every hour, on the day of the equinox.

No matter where you are on Earth – except at the Earth’s North and South Poles – you have a due east and due west point on your horizon. That point marks the intersection of your horizon with the celestial equator: the imaginary line above the true equator of the Earth.

The sun is on the celestial equator, and the celestial equator intersects all of our horizons at points due east and due west. Voila! The sun rises due east and sets due west.

Read more: Sun rises due east and sets due west

The day arc of the sun, every hour, at the equinox, as seen on the (imaginary) celestial sphere surrounding Earth. At the equinox, the sun is directly above Earth’s equator. Image via Tau’olunga/ Wikimedia Commons (CC BY-SA 2.5).

More March equinox effects

And there are also plenty more effects in play around the time of the March equinox that all of us can notice. In the Northern Hemisphere, the March equinox brings earlier sunrises, later sunsets and sprouting plants.

Meanwhile, you’ll find the opposite season – later sunrises, earlier sunsets, chillier winds, dry and falling leaves – south of the equator.

The equinoxes and solstices are caused by Earth’s tilt on its axis and ceaseless motion in orbit. You can think of an equinox as happening on the imaginary dome of our sky, or as an event that happens in Earth’s orbit around the sun.

The Earth-centered view

If you think of it from an Earth-centered perspective, you can think of the celestial equator as a great circle dividing Earth’s sky into its Northern and Southern Hemispheres. The celestial equator is an imaginary line wrapping the sky directly above Earth’s equator. At the equinox, the sun crosses the celestial equator to enter the sky’s Northern Hemisphere.

The day arc of the equinox sun as seen from Earth’s equator. Also showing are twilight suns (in red) down to -18 degrees altitude. Note that the sun is at its highest point at noon. And see that the tree’s shadow at noon is cast straight down. That is – as seen from the equator on the day of an equinox – a tree stands in the center of its own shadow. Image via Tau’olunga/ Wikimedia Commons (CC BY-SA 2.5).

The Earth-in-space view

If you think of it from an Earth-in-space perspective, you have to think of Earth in orbit around the sun. And we all know Earth doesn’t orbit upright but is instead tilted on its axis by 23 1/2 degrees. So Earth’s Northern and Southern Hemispheres trade places in receiving the sun’s light and warmth most directly. We have an equinox twice a year – spring and fall – when the tilt of the Earth’s axis and Earth’s orbit around the sun combine in such a way that the axis is inclined neither away from nor toward the sun.

Here are satellite views of Earth on the solstices and equinoxes, via NASA Earth Observatory.

Things change fast around the equinoxes

Since Earth never stops moving around the sun, the position of the sunrise and sunset – and the days of approximately equal sunlight and night – will change quickly.

The video below was the Astronomy Picture of the Day for March 19, 2014. APOD explained:

At an equinox, the Earth’s terminator – the dividing line between day and night – becomes vertical and connects the North and South Poles. The time-lapse video [above] demonstrates this by displaying an entire year on planet Earth in 12 seconds. From geosynchronous orbit, the Meteosat satellite recorded these infrared images of the Earth every day at the same local time. The video started at the September 2010 equinox with the terminator line being vertical.

As the Earth revolved around the sun, the terminator was seen to tilt in a way that provides less daily sunlight to the Northern Hemisphere, causing winter in the north. As the year progressed, the March 2011 equinox arrived halfway through the video, followed by the terminator tilting the other way, causing winter in the Southern Hemisphere and summer in the north. The captured year ends again with the September equinox, concluding another of billions of trips the Earth has taken – and will take – around the sun.

The equinox is an event that takes place in Earth’s orbit around the sun. Image via National Weather Service/ weather.gov.

Where are signs of the March equinox in nature?

Everywhere! Forget about the weather for a moment, and think only about daylight. In terms of daylight, the knowledge that spring is here – and summer is coming – permeates all of nature on the northern half of Earth’s globe.

Notice the arc of the sun across the sky each day. You’ll find that it’s shifting toward the north. Responding to the change in daylight, birds and butterflies are migrating back northward, too, along with the path of the sun.

The longer days do bring with them warmer weather. People are leaving their winter coats at home. Trees are budding, and plants are beginning a new cycle of growth. In many places, spring flowers are beginning to bloom.

Meanwhile, in the Southern Hemisphere, the days are getting shorter and nights longer. A chill is in the air. Fall is here, and winter is coming!

Bottom line: Happy equinox! The 2026 March equinox falls March 20 at 14:46 UTC. All you need to know about the March equinox here.

The post March equinox 2026: Here’s all you need to know first appeared on EarthSky.

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Happy Pi Day! Ways to celebrate here

We know what pie is, but what is pi? It’s the number that results from dividing the circumference of any circle by its diameter. Although pi is an infinite number, it’s usually rounded off to 3.14. Hence, Pi Day on March 14! Image via Delft University of Technology/ Wikimedia Commons.

Have you heard of Pi Day? It happens every year on March 14. The numbers 3-1-4 are the first three digits of the famous mathematical constant pi, which, in case you’re wondering, is the ratio of the circumference of a circle to its diameter.

No matter how large or small the circle, that ratio always works out to 3.14. That’s the magic of mathematics.

Plus, pi is a never-ending number. You often see it written as 3.14, but in fact it’s approximately equal to 3.14159 … and so on, into infinity. That sense of infinity is in part what makes pi – and Pi Day – so much fun.

So here’s a quick guide to Pi Day, which is celebrated by science aficionados all over the world. It is a unique combination of fun and education, and anyone can participate.

What is pi? It’s the number that results from dividing the circumference of any circle by its diameter. Although pi is an infinite number, it’s usually rounded off to 3.14. Hence, Pi Day on March 14! Image via NASA/ JPL-Caltech.

You deserve a daily dose of good news. For the latest in science and the night sky, click here to subscribe to our free daily newsletter.

5 facts about pi

People compete in memorizing it. Rajveer Meena has the record for memorizing the most decimal places of pi at 70,000.

It’s used as stress tests for computers. Computing pi is a kind of “digital cardiogram” for computers.

A Givenchy men’s cologne is named pi. So you can smell like pi, too, if you are the intellectual and visionary kind.

Pi by other names. Pi is also known as Archimedes’ constant or Ludolph’s number.

Heroes sometimes use pi. For example, Spock foils an evil computer in Wolf in the Fold (the 14th episode of the second season of the American sci-fi TV series “Star Trek”), by preoccupying it forever by having it calculate pi’s value.

By happy coincidence, March 14 is also Albert Einstein’s birthday!

Here are a couple of other online sources to help you celebrate Pi Day:

Join the Exploratorium’s annual celebration.

Check out this Pi Day overview.

Or enjoy some trivia via National Today.

Happy Pi Day! Pi is a mathematical constant. It equals 3.14159 … and so on, into infinity. So for short, we refer to pi as 3.14. Image via NASA/ JPL-Caltech.

History of Pi Day

Physicist Larry Shaw founded Pi Day in 1988, as part of his great work at the ground-breaking science museum Exploratorium in San Francisco. During the first festivities, both staff and the public marched around one of the circular spaces in the museum while eating fruit pies.

In the United States, the U.S. House of Representatives officially recognized Pi Day as an annual event – National Pi Day – on March 12, 2009.

Today, many people and institutions celebrate, including students, teachers, parents, museums, science centers and planetariums.

Physicist Larry Shaw founded Pi Day in 1988 at the famous Exploratorium science museum in San Francisco. Image via Ronhip/ Wikimedia Commons (CC BY-SA 3.0).

Celebrate Pi Day with NASA

At the NASA site you can find many resources, including a Pi Day Challenge, along with lessons and downloads. The challenge allows the public to solve some of the same problems NASA scientists and engineers do using pi.

Take part in the NASA Pi Day Challenge and find a list of handy resources below. Image via NASA/ JPL.

More NASA resources

Here are more resources and ways you can celebrate, including:

18 Ways NASA Uses Pi

How Many Decimals of Pi Do We Really Need?

Pi in the Sky Lessons

Infographic: Planet Pi

In addition, you can also download mobile and web backgrounds on The NASA Pi Day Challenge page.

A ‘pi planet’

By the way, did you know that there’s even a pi planet? It is an exoplanet known as K2-315b, whose orbital period matches the value of pi. That is, this planet orbits its star every 3.14 Earth days.

It is, in fact, almost the same size as Earth, with a radius 95% that of our own planet. That’s also about the same size as Venus, and like our nearby sister world, it’s a blisteringly hot place, with temperatures up to 350 degrees Fahrenheit (177 degrees C). It orbits a red dwarf (or M-type dwarf) star that’s cooler than our sun and only about 1/5 as large, called EPIC 249631677, which is 186 light-years from Earth.

There is even a “pi planet.” This is an artist’s concept of K2-315b, which has an orbital period of 3.14 Earth days, the same value as pi. Image via NASA Ames/ JPL-Caltech/ T. Pyle/ Christine Daniloff/ MIT (CC BY-NC-ND 4.0).

Bottom line: March 14 is Pi Day, an annual mathematical event for science lovers. Here’s how to celebrate and take part in the NASA Pi Day Challenge!

Via NASA

Via piday.org

The post Happy Pi Day! Ways to celebrate here first appeared on EarthSky.

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We know what pie is, but what is pi? It’s the number that results from dividing the circumference of any circle by its diameter. Although pi is an infinite number, it’s usually rounded off to 3.14. Hence, Pi Day on March 14! Image via Delft University of Technology/ Wikimedia Commons.

Have you heard of Pi Day? It happens every year on March 14. The numbers 3-1-4 are the first three digits of the famous mathematical constant pi, which, in case you’re wondering, is the ratio of the circumference of a circle to its diameter.

No matter how large or small the circle, that ratio always works out to 3.14. That’s the magic of mathematics.

Plus, pi is a never-ending number. You often see it written as 3.14, but in fact it’s approximately equal to 3.14159 … and so on, into infinity. That sense of infinity is in part what makes pi – and Pi Day – so much fun.

So here’s a quick guide to Pi Day, which is celebrated by science aficionados all over the world. It is a unique combination of fun and education, and anyone can participate.

What is pi? It’s the number that results from dividing the circumference of any circle by its diameter. Although pi is an infinite number, it’s usually rounded off to 3.14. Hence, Pi Day on March 14! Image via NASA/ JPL-Caltech.

You deserve a daily dose of good news. For the latest in science and the night sky, click here to subscribe to our free daily newsletter.

5 facts about pi

People compete in memorizing it. Rajveer Meena has the record for memorizing the most decimal places of pi at 70,000.

It’s used as stress tests for computers. Computing pi is a kind of “digital cardiogram” for computers.

A Givenchy men’s cologne is named pi. So you can smell like pi, too, if you are the intellectual and visionary kind.

Pi by other names. Pi is also known as Archimedes’ constant or Ludolph’s number.

Heroes sometimes use pi. For example, Spock foils an evil computer in Wolf in the Fold (the 14th episode of the second season of the American sci-fi TV series “Star Trek”), by preoccupying it forever by having it calculate pi’s value.

By happy coincidence, March 14 is also Albert Einstein’s birthday!

Here are a couple of other online sources to help you celebrate Pi Day:

Join the Exploratorium’s annual celebration.

Check out this Pi Day overview.

Or enjoy some trivia via National Today.

Happy Pi Day! Pi is a mathematical constant. It equals 3.14159 … and so on, into infinity. So for short, we refer to pi as 3.14. Image via NASA/ JPL-Caltech.

History of Pi Day

Physicist Larry Shaw founded Pi Day in 1988, as part of his great work at the ground-breaking science museum Exploratorium in San Francisco. During the first festivities, both staff and the public marched around one of the circular spaces in the museum while eating fruit pies.

In the United States, the U.S. House of Representatives officially recognized Pi Day as an annual event – National Pi Day – on March 12, 2009.

Today, many people and institutions celebrate, including students, teachers, parents, museums, science centers and planetariums.

Physicist Larry Shaw founded Pi Day in 1988 at the famous Exploratorium science museum in San Francisco. Image via Ronhip/ Wikimedia Commons (CC BY-SA 3.0).

Celebrate Pi Day with NASA

At the NASA site you can find many resources, including a Pi Day Challenge, along with lessons and downloads. The challenge allows the public to solve some of the same problems NASA scientists and engineers do using pi.

Take part in the NASA Pi Day Challenge and find a list of handy resources below. Image via NASA/ JPL.

More NASA resources

Here are more resources and ways you can celebrate, including:

18 Ways NASA Uses Pi

How Many Decimals of Pi Do We Really Need?

Pi in the Sky Lessons

Infographic: Planet Pi

In addition, you can also download mobile and web backgrounds on The NASA Pi Day Challenge page.

A ‘pi planet’

By the way, did you know that there’s even a pi planet? It is an exoplanet known as K2-315b, whose orbital period matches the value of pi. That is, this planet orbits its star every 3.14 Earth days.

It is, in fact, almost the same size as Earth, with a radius 95% that of our own planet. That’s also about the same size as Venus, and like our nearby sister world, it’s a blisteringly hot place, with temperatures up to 350 degrees Fahrenheit (177 degrees C). It orbits a red dwarf (or M-type dwarf) star that’s cooler than our sun and only about 1/5 as large, called EPIC 249631677, which is 186 light-years from Earth.

There is even a “pi planet.” This is an artist’s concept of K2-315b, which has an orbital period of 3.14 Earth days, the same value as pi. Image via NASA Ames/ JPL-Caltech/ T. Pyle/ Christine Daniloff/ MIT (CC BY-NC-ND 4.0).

Bottom line: March 14 is Pi Day, an annual mathematical event for science lovers. Here’s how to celebrate and take part in the NASA Pi Day Challenge!

Via NASA

Via piday.org

The post Happy Pi Day! Ways to celebrate here first appeared on EarthSky.

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Our sun might be a migrant from the inner Milky Way

A new study suggests our sun might be a migrant from a more central region of our home galaxy, the Milky Way. It suggests our sun joined a migration of other stars, which moved outward from the inner part of the galaxy some 4 to 6 billion years ago. Image via NAOJ/ EurekaAlert.

• Astronomers suggest the sun might have migrated from near the central bar-shaped nucleus of our Milky Way galaxy.
• Scientists studied 6,594 solar “twin” stars, using Gaia data. Many share the sun’s age (about 4–6 billion years) and appear to have migrated outward from the galaxy’s inner regions together.
• The sun eventually took up residence in a quieter part of the galaxy, where planets (and life) could develop with fewer threats.

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

Our sun might be a migrant

Astronomers have long thought our sun was born closer to the center of our Milky Way galaxy than it is today.

The stumbling block to that idea has been the Milky Way’s huge central bar, which is essentially a massive gravitational engine. The galaxy’s central bar creates its own high-pressure, high-energy environment, where stars are being born and dying, and where energetic events like supernovas happen frequently. So it’s not a nice, quiet part of the galaxy for the founding and evolution of life.

Previous studies had shown the gravitational pull of this bar served as a barrier for escaping stars. But now a new study from Tokyo Metropolitan University – and reported by EurekAlert on March 12, 2026 – suggests that, as the central bar was forming somewhere between 4 and 6 billion years ago, it triggered both star formation and a wave of outward migration for stars … maybe including our sun.

How do we know?

Assistant professors Daisuke Taniguchi at Tokyo Metropolitan University and Takuji Tsujimoto at the National Astronomical Observatory of Japan led the new studies. They looked at stars that are similar to our sun – a G-type star – in terms of temperature, composition and surface gravity. Altogether, the survey included 6,594 of these virtual twins to our sun. That was out of the overall observations of 2 billion stars.

The data came from the European Space Agency’s amazing Gaia spacecraft. Gaia did what’s called astrometry. In other words, it obtained precise measurements of the positions of stars, over and over again. In this way, it revealed the movement of stars in our galaxy for more than a decade. The data showed there was a mass movement of stars, out of the turbulent inner galactic regions to more serene pastures.

Out here, farther from our galaxy’s core and its central bar, our sun now resides in a quieter part of the galaxy. And this could have big implications for why life could arise on Earth, and possibly on planets around similar stars in our neighborhood.

The researchers published two new papers in the peer-reviewed journal Astronomy and Astrophysics on March 12, 2026.

Our current place in the Milky Way

The sun and solar system lie about 25,000 light-years from the center of the Milky Way. And the central bar in the Milky Way extends some 10,000 to 15,000 light-years from its center. The 4.6-billion-year-old sun is in the Orion-Cygnus Arm, or Orion Spur, a minor spiral arm of the Milky Way galaxy.

The new study suggests our sun began its life in the galaxy at more than 10,000 light-years nearer to the galactic center than we are today. That would have put us close to the central bar.

But the central bar has a gravitational effect that scientists call a corotation barrier. Basically, its pull of gravity makes it hard for stars to travel far away from the bar. Enter the new study. It suggests the bar wasn’t fully formed until after the sun – and thousands of similar stars – made their escape.

A graphic of the Milky Way showing our solar system’s current location in our galaxy. Note our distance from the central bar. Image via Universität Wien.

Migrating to a safer neighborhood

The scientists who conducted the new study looked at a notable concentration of stars that are around 4 to 6 billion years old, similar in age to our sun. And they all currently inhabit a region of the galaxy that’s about the same distance from the center as we are.

The scientists concluded that the age and locations of these stars are evidence of a stellar migration. They said these stars and our sun were able to escape the gravity of the still-forming bar region. The stars made a mass exodus from a region that was, coincidentally, hostile to the formation of life.

Afterward, our sun and its planets – along with thousands of similar sibling stars – came to live in a quieter galactic neighborhood. It’s a region of the Milky Way where life was able to – at least once – evolve in relative peace.

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A new view of the heart of the Milky Way

By the way, researchers using the Atacama Large Millimeter/submillimeter Array (ALMA) in Chile recently took a stunning new, detailed image of a molecular cloud feature in the heart of the Milky Way.

They captured the huge image in millimeter radio wavelengths. It revealed new details of a chaotic gaseous region with massive stars that orbits the supermassive black hole in our galaxy’s center. See it here, or watch the video below.

This brief video gives you a look at the new image of the Milky Way center taken in radio wavelengths. It’s the largest image the Atacama Large Millimeter/submillimeter Array (ALMA) in Chile has ever taken. Video via ALMA (ESO/ NAOJ/ NRAO)/ S. Longmore et al. Background: ESO/ D. Minniti et al.

Bottom line: A new study suggests the sun might be a migrant that was born in the inner galaxy and journeyed outward. Researchers believe it made that crossing in the company of many other stars similar to our sun.

Source: Solar twins in Gaia DR3 GSP-Spec I. Building a large catalog of solar twins with ages

Source: Solar twins in Gaia DR3 GSP-Spec II. Age distribution and its implications for the Sun’s migration

Via EurekAlert

The post Our sun might be a migrant from the inner Milky Way first appeared on EarthSky.

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A new study suggests our sun might be a migrant from a more central region of our home galaxy, the Milky Way. It suggests our sun joined a migration of other stars, which moved outward from the inner part of the galaxy some 4 to 6 billion years ago. Image via NAOJ/ EurekaAlert.

• Astronomers suggest the sun might have migrated from near the central bar-shaped nucleus of our Milky Way galaxy.
• Scientists studied 6,594 solar “twin” stars, using Gaia data. Many share the sun’s age (about 4–6 billion years) and appear to have migrated outward from the galaxy’s inner regions together.
• The sun eventually took up residence in a quieter part of the galaxy, where planets (and life) could develop with fewer threats.

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Our sun might be a migrant

Astronomers have long thought our sun was born closer to the center of our Milky Way galaxy than it is today.

The stumbling block to that idea has been the Milky Way’s huge central bar, which is essentially a massive gravitational engine. The galaxy’s central bar creates its own high-pressure, high-energy environment, where stars are being born and dying, and where energetic events like supernovas happen frequently. So it’s not a nice, quiet part of the galaxy for the founding and evolution of life.

Previous studies had shown the gravitational pull of this bar served as a barrier for escaping stars. But now a new study from Tokyo Metropolitan University – and reported by EurekAlert on March 12, 2026 – suggests that, as the central bar was forming somewhere between 4 and 6 billion years ago, it triggered both star formation and a wave of outward migration for stars … maybe including our sun.

How do we know?

Assistant professors Daisuke Taniguchi at Tokyo Metropolitan University and Takuji Tsujimoto at the National Astronomical Observatory of Japan led the new studies. They looked at stars that are similar to our sun – a G-type star – in terms of temperature, composition and surface gravity. Altogether, the survey included 6,594 of these virtual twins to our sun. That was out of the overall observations of 2 billion stars.

The data came from the European Space Agency’s amazing Gaia spacecraft. Gaia did what’s called astrometry. In other words, it obtained precise measurements of the positions of stars, over and over again. In this way, it revealed the movement of stars in our galaxy for more than a decade. The data showed there was a mass movement of stars, out of the turbulent inner galactic regions to more serene pastures.

Out here, farther from our galaxy’s core and its central bar, our sun now resides in a quieter part of the galaxy. And this could have big implications for why life could arise on Earth, and possibly on planets around similar stars in our neighborhood.

The researchers published two new papers in the peer-reviewed journal Astronomy and Astrophysics on March 12, 2026.

Our current place in the Milky Way

The sun and solar system lie about 25,000 light-years from the center of the Milky Way. And the central bar in the Milky Way extends some 10,000 to 15,000 light-years from its center. The 4.6-billion-year-old sun is in the Orion-Cygnus Arm, or Orion Spur, a minor spiral arm of the Milky Way galaxy.

The new study suggests our sun began its life in the galaxy at more than 10,000 light-years nearer to the galactic center than we are today. That would have put us close to the central bar.

But the central bar has a gravitational effect that scientists call a corotation barrier. Basically, its pull of gravity makes it hard for stars to travel far away from the bar. Enter the new study. It suggests the bar wasn’t fully formed until after the sun – and thousands of similar stars – made their escape.

A graphic of the Milky Way showing our solar system’s current location in our galaxy. Note our distance from the central bar. Image via Universität Wien.

Migrating to a safer neighborhood

The scientists who conducted the new study looked at a notable concentration of stars that are around 4 to 6 billion years old, similar in age to our sun. And they all currently inhabit a region of the galaxy that’s about the same distance from the center as we are.

The scientists concluded that the age and locations of these stars are evidence of a stellar migration. They said these stars and our sun were able to escape the gravity of the still-forming bar region. The stars made a mass exodus from a region that was, coincidentally, hostile to the formation of life.

Afterward, our sun and its planets – along with thousands of similar sibling stars – came to live in a quieter galactic neighborhood. It’s a region of the Milky Way where life was able to – at least once – evolve in relative peace.

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A new view of the heart of the Milky Way

By the way, researchers using the Atacama Large Millimeter/submillimeter Array (ALMA) in Chile recently took a stunning new, detailed image of a molecular cloud feature in the heart of the Milky Way.

They captured the huge image in millimeter radio wavelengths. It revealed new details of a chaotic gaseous region with massive stars that orbits the supermassive black hole in our galaxy’s center. See it here, or watch the video below.

This brief video gives you a look at the new image of the Milky Way center taken in radio wavelengths. It’s the largest image the Atacama Large Millimeter/submillimeter Array (ALMA) in Chile has ever taken. Video via ALMA (ESO/ NAOJ/ NRAO)/ S. Longmore et al. Background: ESO/ D. Minniti et al.

Bottom line: A new study suggests the sun might be a migrant that was born in the inner galaxy and journeyed outward. Researchers believe it made that crossing in the company of many other stars similar to our sun.

Source: Solar twins in Gaia DR3 GSP-Spec I. Building a large catalog of solar twins with ages

Source: Solar twins in Gaia DR3 GSP-Spec II. Age distribution and its implications for the Sun’s migration

Via EurekAlert

The post Our sun might be a migrant from the inner Milky Way first appeared on EarthSky.

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NASA helps giant tortoises return to a Galápagos island

After 150 years, giant tortoises are back on Floreana! Watch as 158 tortoises take their first steps into the wild, guided by cutting-edge NASA data. Video via EarthSky.

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NASA helps giant tortoises return to a Galápagos island

For the first time in more than 150 years, giant tortoises are roaming the wild again on Floreana Island in the Galápagos. On February 20, 2026, conservation teams from the Galápagos National Park Directorate and the Galápagos Conservancy released 158 tortoises at two sites. They chose those sites using NASA satellite data, identifying areas where the animals could easily find food, water and nesting locations.

Keith Gaddis, manager of NASA Earth Action’s Biological Diversity and Ecological Forecasting program, said:

This is exactly the kind of project where NASA Earth observations make a difference. We’re helping partners answer a practical question: where will these animals have the best chance to survive, not just today, but decades from now?

Giant tortoises: A history lost and found

Giant tortoises disappeared from Floreana in the mid-1800s. The Floreana giant tortoise went extinct due to a few reasons. First, sailors arrived and hunted the animals for their meat. The tortoises could be stored alive on ships for up to six months, providing fresh food in other locations. But sailors also introduced predators, such as pigs and rats, which preyed on tortoise eggs and hatchlings.

So, without the tortoises, the island began to change. Historically, giant tortoises helped shape the landscape. They grazed on vegetation, opening pathways through dense plant growth and carrying seeds.

The path to reintroduction began decades later. In 2000, James Gibbs, Vice President of Science and Conservation at the Galápagos Conservancy, and other researchers discovered unusual tortoises on Wolf Volcano in northern Isabela Island. They did not resemble any known living species.

About 10 years later, scientists compared DNA from these animals with genetic material from bones of extinct Floreana tortoises from caves and museums. The analysis confirmed some of the Wolf Volcano tortoises carried Floreana ancestry. These tortoises were a sort of hybrid. It seems as if the sailors, in moving the tortoises on their ships, at one point dropped some off on Isabela Island more than a century ago.

Scientists then used these hybrid tortoises to establish a breeding program. And it has produced hundreds of offspring that are now ready to return to Floreana.

From extinction to revival: Hybrid tortoises with Floreana ancestry are paving the way for the giant tortoise’s return to its historic island home. Image via David Liberio/ Galápagos Conservancy. Used with permission.

Matching tortoises with the right habitat

Releasing tortoises into the wild is not as simple as opening a gate. Young tortoises raised in captivity must learn to find food, water and nesting sites. Gibbs said:

They don’t know where food is; they don’t know where water is; they don’t know where to nest. If you can place them where conditions are already right, you give them a much better chance.

Floreana’s terrain adds another layer of challenge. Some hills and mountains capture clouds and support cool, moist forests. Meanwhile, lower areas remain dry most of the year. Because tortoises need both food and nesting areas, they naturally migrate between these contrasting habitats. Thanks to NASA satellite data, researchers can identify the best release sites.

This Landsat 8 image of Floreana Island from October 6, 2020, shows dry coastal lowlands surrounding greener, higher-elevation vegetation toward the island’s center. Image via Wanmei Liang/ NASA Earth Observatory.

Using NASA data to guide release of giant tortoises

NASA satellite data play a key role in understanding these movement patterns. Observations track vegetation, rainfall, moisture and land-surface temperatures across the islands. Thus, the data highlight the areas most suitable for tortoises.

The project’s team, including professor Giorgos Mountrakis at the State University of New York College, created a decision tool. It combines satellite measurements with millions of field observations of tortoise locations. The tool maps habitat suitability today and predicts conditions decades into the future. This is crucial for an animal that can live over a century. Giorgos Mountrakis said:

This isn’t a one-year project. We’re looking at where tortoises will succeed 20, 40 years from now.

The scientists used various satellites in the project. They include Landsat and European Sentinel, which monitors vegetation, the Global Precipitation Measurement mission, which provides rainfall information, and Terra, which measures land-surface temperature. Also, teams used high-resolution commercial satellite imagery from NASA’s Commercial Smallsat Data Acquisition Program. All these data allowed them to evaluate potential release sites before conducting field surveys.

Christian Sevilla, director of ecosystems at the Galápagos National Park Directorate, said:

Habitat suitability models and environmental mapping are essential tools. They allow us to integrate climate, topography and vegetation data to make evidence-based decisions. We move from intuition to precision.

This map shows modeled giant tortoise habitat suitability across the Galápagos under current environmental conditions. Colors from dark to light indicate increasing likelihood of suitable food, moisture and nesting habitat availability. Image via Wanmei Liang/ NASA Earth Observatory.

Restoring Floreana’s ecosystem

The tortoise release is part of the broader Floreana Ecological Restoration Project. This project focuses on removing invasive species such as rats and feral cats that threaten eggs and hatchlings. Eventually, the plan is that 12 native animal species will return, with giant tortoises serving as a keystone species to help rebuild ecological processes.

Over the past six decades, the Galápagos National Park Directorate has raised and released more than 10,000 tortoises across the archipelago. It’s one of the largest rewilding efforts ever attempted.

Each island presents unique challenges because of differences in vegetation, moisture and terrain. Combining long-term field observations with NASA data helps scientists anticipate how tortoises will interact with these environments. Plus, they can assess habitat changes forecast for decades ahead.

If successful, Floreana could once again support a thriving tortoise population. It could restore the interactions between animals, plants and landscapes that have shaped the island for thousands of years. Sevilla said:

For those of us who live and work in Galápagos, this release is deeply meaningful. It demonstrates that large-scale ecological restoration is possible and that, with science and long-term commitment, we can recover an essential part of the archipelago’s natural heritage.

Carrying hope on their backs: Conservation teams transport young giant tortoises to carefully chosen release sites, giving Floreana Island’s ecosystem a second chance after more than a century. Image via David Liberio/ Galápagos Conservancy. Used with permission.

Bottom line: Giant tortoises return to Floreana Island in the Galápagos. NASA satellites are guiding their release and helping revive the island’s wild ecosystem.

Via NASA

Read more: Galápagos giant tortoises migrate, albeit slowly and not too far

Read more: Sea turtles are as old as dinosaurs: Lifeform of the week

The post NASA helps giant tortoises return to a Galápagos island first appeared on EarthSky.

from EarthSky https://ift.tt/yufFtw3

After 150 years, giant tortoises are back on Floreana! Watch as 158 tortoises take their first steps into the wild, guided by cutting-edge NASA data. Video via EarthSky.

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

NASA helps giant tortoises return to a Galápagos island

For the first time in more than 150 years, giant tortoises are roaming the wild again on Floreana Island in the Galápagos. On February 20, 2026, conservation teams from the Galápagos National Park Directorate and the Galápagos Conservancy released 158 tortoises at two sites. They chose those sites using NASA satellite data, identifying areas where the animals could easily find food, water and nesting locations.

Keith Gaddis, manager of NASA Earth Action’s Biological Diversity and Ecological Forecasting program, said:

This is exactly the kind of project where NASA Earth observations make a difference. We’re helping partners answer a practical question: where will these animals have the best chance to survive, not just today, but decades from now?

Giant tortoises: A history lost and found

Giant tortoises disappeared from Floreana in the mid-1800s. The Floreana giant tortoise went extinct due to a few reasons. First, sailors arrived and hunted the animals for their meat. The tortoises could be stored alive on ships for up to six months, providing fresh food in other locations. But sailors also introduced predators, such as pigs and rats, which preyed on tortoise eggs and hatchlings.

So, without the tortoises, the island began to change. Historically, giant tortoises helped shape the landscape. They grazed on vegetation, opening pathways through dense plant growth and carrying seeds.

The path to reintroduction began decades later. In 2000, James Gibbs, Vice President of Science and Conservation at the Galápagos Conservancy, and other researchers discovered unusual tortoises on Wolf Volcano in northern Isabela Island. They did not resemble any known living species.

About 10 years later, scientists compared DNA from these animals with genetic material from bones of extinct Floreana tortoises from caves and museums. The analysis confirmed some of the Wolf Volcano tortoises carried Floreana ancestry. These tortoises were a sort of hybrid. It seems as if the sailors, in moving the tortoises on their ships, at one point dropped some off on Isabela Island more than a century ago.

Scientists then used these hybrid tortoises to establish a breeding program. And it has produced hundreds of offspring that are now ready to return to Floreana.

From extinction to revival: Hybrid tortoises with Floreana ancestry are paving the way for the giant tortoise’s return to its historic island home. Image via David Liberio/ Galápagos Conservancy. Used with permission.

Matching tortoises with the right habitat

Releasing tortoises into the wild is not as simple as opening a gate. Young tortoises raised in captivity must learn to find food, water and nesting sites. Gibbs said:

They don’t know where food is; they don’t know where water is; they don’t know where to nest. If you can place them where conditions are already right, you give them a much better chance.

Floreana’s terrain adds another layer of challenge. Some hills and mountains capture clouds and support cool, moist forests. Meanwhile, lower areas remain dry most of the year. Because tortoises need both food and nesting areas, they naturally migrate between these contrasting habitats. Thanks to NASA satellite data, researchers can identify the best release sites.

This Landsat 8 image of Floreana Island from October 6, 2020, shows dry coastal lowlands surrounding greener, higher-elevation vegetation toward the island’s center. Image via Wanmei Liang/ NASA Earth Observatory.

Using NASA data to guide release of giant tortoises

NASA satellite data play a key role in understanding these movement patterns. Observations track vegetation, rainfall, moisture and land-surface temperatures across the islands. Thus, the data highlight the areas most suitable for tortoises.

The project’s team, including professor Giorgos Mountrakis at the State University of New York College, created a decision tool. It combines satellite measurements with millions of field observations of tortoise locations. The tool maps habitat suitability today and predicts conditions decades into the future. This is crucial for an animal that can live over a century. Giorgos Mountrakis said:

This isn’t a one-year project. We’re looking at where tortoises will succeed 20, 40 years from now.

The scientists used various satellites in the project. They include Landsat and European Sentinel, which monitors vegetation, the Global Precipitation Measurement mission, which provides rainfall information, and Terra, which measures land-surface temperature. Also, teams used high-resolution commercial satellite imagery from NASA’s Commercial Smallsat Data Acquisition Program. All these data allowed them to evaluate potential release sites before conducting field surveys.

Christian Sevilla, director of ecosystems at the Galápagos National Park Directorate, said:

Habitat suitability models and environmental mapping are essential tools. They allow us to integrate climate, topography and vegetation data to make evidence-based decisions. We move from intuition to precision.

This map shows modeled giant tortoise habitat suitability across the Galápagos under current environmental conditions. Colors from dark to light indicate increasing likelihood of suitable food, moisture and nesting habitat availability. Image via Wanmei Liang/ NASA Earth Observatory.

Restoring Floreana’s ecosystem

The tortoise release is part of the broader Floreana Ecological Restoration Project. This project focuses on removing invasive species such as rats and feral cats that threaten eggs and hatchlings. Eventually, the plan is that 12 native animal species will return, with giant tortoises serving as a keystone species to help rebuild ecological processes.

Over the past six decades, the Galápagos National Park Directorate has raised and released more than 10,000 tortoises across the archipelago. It’s one of the largest rewilding efforts ever attempted.

Each island presents unique challenges because of differences in vegetation, moisture and terrain. Combining long-term field observations with NASA data helps scientists anticipate how tortoises will interact with these environments. Plus, they can assess habitat changes forecast for decades ahead.

If successful, Floreana could once again support a thriving tortoise population. It could restore the interactions between animals, plants and landscapes that have shaped the island for thousands of years. Sevilla said:

For those of us who live and work in Galápagos, this release is deeply meaningful. It demonstrates that large-scale ecological restoration is possible and that, with science and long-term commitment, we can recover an essential part of the archipelago’s natural heritage.

Carrying hope on their backs: Conservation teams transport young giant tortoises to carefully chosen release sites, giving Floreana Island’s ecosystem a second chance after more than a century. Image via David Liberio/ Galápagos Conservancy. Used with permission.

Bottom line: Giant tortoises return to Floreana Island in the Galápagos. NASA satellites are guiding their release and helping revive the island’s wild ecosystem.

Via NASA

Read more: Galápagos giant tortoises migrate, albeit slowly and not too far

Read more: Sea turtles are as old as dinosaurs: Lifeform of the week

The post NASA helps giant tortoises return to a Galápagos island first appeared on EarthSky.

from EarthSky https://ift.tt/yufFtw3

2026 has 3 Friday the 13ths. What are the odds?

In 2026, there are 3 Friday the 13ths. They are in February, March and November. Do you believe Friday the 13th is a bad day? An unlucky day? See below to explore the myths and the legacy behind Friday the 13th. Image via Wikimedia Commons.

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

March 13, 2026, is a Friday, and it’s Act 2 of this year’s epic Friday the 13th trilogy. Plus, we’ll also have another Friday the 13th in November. We started off this year’s trilogy with a Friday the 13th in February, exactly 4 weeks before Friday, March 13, 2026!

Not that we at EarthSky suffer from friggatriskaidekaphobia – an irrational fear of Friday the 13th – but, gosh darn, it’s Friday the 13th three times over in 2026. What’s more, last year’s lone Friday the 13th on June 13, 2025, occurred exactly 39 weeks (3 x 13 weeks) before the Friday the 13th in March 2026. And next year’s lone Friday the 13th on August 13, 2027, will happen exactly 39 weeks (3 x 13 weeks) after the Friday the 13th in November 2026. Follow the links below to learn more about why some people fear this day and about 2015’s three Friday the 13ths.

Gioachino Rossini, a 19th century Italian composer. Folklorists say there’s no written evidence that Friday the 13th was considered unlucky before the 19th century. The earliest known documented reference in English appears to be in Henry Sutherland Edwards’ 1869 biography of Rossini. Image via Wikimedia Commons.

Scary coincidence or super unlucky?

It’s neither a scary coincidence or super unlucky. It’s just a quirk of our calendar, as you’ll see if you keep reading.

The fact is that, according to folklorists, there’s no written evidence that Friday the 13th was considered unlucky before the 19th century. The earliest known documented reference in English appears to be in Henry Sutherland Edwards’ 1869 biography of Gioachino Rossini. His portrait is above. He doesn’t look scary.

And indeed, Friday has always gotten a bad rap. In the Middle Ages, people would not marry – or set out on a journey – on a Friday.

There are also some links between Christianity and an ill association with either Fridays or the number 13. Jesus was said to be crucified on a Friday. Seating 13 people at a table was seen as bad luck because Judas Iscariot, the disciple who betrayed Jesus, is said to have been the 13th guest at the Last Supper. Meanwhile, our word for Friday comes from Frigga, an ancient Scandinavian fertility and love goddess. Christians called Frigga a witch and Friday the witches’ Sabbath.

In modern times, the slasher-movie franchise Friday the 13th has helped keep friggatriskaidekaphobia alive.

The Friday the 13th slasher-movie franchise helped keep this day maintain its notoriety. Image via Wikimedia Commons.

In 2026, blame Thursday

In 2026, you can blame Thursday because the year started on a Thursday. Whenever a common year of 365 days starts on a Thursday, it’s inevitable that the months of February, March and November will start on a Sunday. And any month starting on a Sunday always has a Friday the 13th.

Of course, February has exactly four weeks in a non-leap year. So, for that reason, the days of the week have to match up with the same dates in both February and March during any common year. And in any year, the days of the week always fall on the same dates in both March and November. In short, because the year 2026 started on a Thursday, that means February, March and November all have to start on a Sunday and all must have a Friday the 13th.

The February-March-November Friday the 13th trilogy repeats …

How often does the February-March-November Friday the 13th trilogy repeat? More often than you might imagine! The last February-March-November Friday the 13th year happened 11 years ago, in 2015, for the second time in the 21st century (2001-2100). It will next happen eleven years from now, in 2037. After that, the following February-March-November Friday the 13th year will happen six years after 2037, in the year 2043.

A grand total of eleven February-March-November Friday the 13th years takes place in the 21st century (2001-2100):

2009, 2015, 2026, 2037, 2043, 2054, 2065, 2071, 2082, 2093 and 2099

And because the Gregorian calendar has a 400-year cycle, we also know the February-March-November Friday the 13th years will repeat exactly 400 years later in the 25th century (2401-2500):

2409, 2415, 2426, 2437, 2443, 2454, 2465, 2471, 2482, 2493 and 2499

Calendar for 2026

Calendar for the year 2026. There are 3 Friday the 13ths. They are in February, March and November. Calendar via EarthSky.

The rhyme and reason of the Friday the 13th cycle

Is there any rhyme and reason to the Friday the 13th cycle? Yes, it does make sense. Within the 21st century (2001-2100), note that the February-March-November Friday the 13th years repeat in 28-year cycles (going crosswise):

2009, 2037, 2065, 2093
2015, 2043, 2071, 2099
2026, 2054, 2082

Because the Gregorian calendar suppresses the leap year in 2100, the cycle is perturbed, meaning that all eleven February-March-November Friday the 13th years in the 22nd century (2101-2200) come four years earlier than in the 21st century:

2105, 2111, 2122, 2133, 2139, 2150, 2161, 2167, 2178, 2189 and 2195.

However, within the 22nd century (2101-2200), these Friday the 13th years also repeat in cycles of 28 years.

2105, 2133, 2161, 2189
2111, 2139, 2167, 2195
2122, 2150, 2178

The cycle is perturbed again in the 23rd century (2201-2300):

2201, 2229, 2257, 2285
2207, 2235, 2263, 2291
2218, 2246, 2274

And again in the 24th century (2301-2400):

2303, 2331, 2359, 2387
2314, 2342, 2370, 2398
2325, 2353, 2381

Friday-the-13th-year repetitions within 28-year cycle

Some of you, who might not yet be dazed by calendar numerology, may wonder if some formula governs how a given Friday the 13th year repeats within the 28-year cycle. The answer is a definite yes. Keep in mind that this particular February-March-November Friday the 13th year can only happen in a common year of 365 days, and when January 1 falls on a Thursday.

Therefore, if this threefold Friday the 13th year comes one year after a leap year, the days again match up with the dates in 6, 17 and 28 years afterward. For example, take the year 2009, which came one year after a leap year:

2009, 2015, 2026, 2037

However, if this triple Friday the 13th year falls two years after a leap year, the days and dates realign in 11, 17 and 28 years. Take this year, 2026, which takes place two years after a leap year:

2026, 2037, 2043, 2054

Finally, if this trio of Friday the 13ths happens three years after a leap year, the days recur with the same dates in 11, 22 and 28 years. The year 2015 happened three years after a leap year:

2015, 2026, 2037, 2043

It appears as though cycles of 372 and 400 years prevail over the long course of centuries. Take the year 2015, for instance:

2015 + 372 = 2387

2015 + 400 = 2415

The 372-year period is known as the Gregoriana eclipse cycle, which we elaborate about in our post: How often does a solar eclipse happen on the March equinox?.

Can three Friday the 13ths occur in a leap year?

What about three Friday the 13ths in a leap year? Yes, a leap year can harbor three Friday the 13ths (January 13 – April 13 – July 13) if the leap year starts on a Sunday, which last happened in 2012. However, given that this particular Friday the 13th year happens in a leap year, and a leap year only, it recurs only in periods of 28 years. So the last January-April-July Friday the 13th year happened in 1984, and will next happen in 2040.

If a common year starts on a Thursday, there are three Friday the 13ths; and if a leap year begins on a Sunday, there are three Friday the 13ths. So these are the two scenarios whereby three Friday the 13ths can occur in single calendar year.

Bottom line: From what we have been able to gather, the 400-year cycle displayed by Gregorian calendar features 59 years with three Friday the 13ths, consisting of 44 common years (February – March – November Friday the 13ths) and 15 leap years (January – April – July Friday the 13ths).

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The post 2026 has 3 Friday the 13ths. What are the odds? first appeared on EarthSky.

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In 2026, there are 3 Friday the 13ths. They are in February, March and November. Do you believe Friday the 13th is a bad day? An unlucky day? See below to explore the myths and the legacy behind Friday the 13th. Image via Wikimedia Commons.

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

March 13, 2026, is a Friday, and it’s Act 2 of this year’s epic Friday the 13th trilogy. Plus, we’ll also have another Friday the 13th in November. We started off this year’s trilogy with a Friday the 13th in February, exactly 4 weeks before Friday, March 13, 2026!

Not that we at EarthSky suffer from friggatriskaidekaphobia – an irrational fear of Friday the 13th – but, gosh darn, it’s Friday the 13th three times over in 2026. What’s more, last year’s lone Friday the 13th on June 13, 2025, occurred exactly 39 weeks (3 x 13 weeks) before the Friday the 13th in March 2026. And next year’s lone Friday the 13th on August 13, 2027, will happen exactly 39 weeks (3 x 13 weeks) after the Friday the 13th in November 2026. Follow the links below to learn more about why some people fear this day and about 2015’s three Friday the 13ths.

Gioachino Rossini, a 19th century Italian composer. Folklorists say there’s no written evidence that Friday the 13th was considered unlucky before the 19th century. The earliest known documented reference in English appears to be in Henry Sutherland Edwards’ 1869 biography of Rossini. Image via Wikimedia Commons.

Scary coincidence or super unlucky?

It’s neither a scary coincidence or super unlucky. It’s just a quirk of our calendar, as you’ll see if you keep reading.

The fact is that, according to folklorists, there’s no written evidence that Friday the 13th was considered unlucky before the 19th century. The earliest known documented reference in English appears to be in Henry Sutherland Edwards’ 1869 biography of Gioachino Rossini. His portrait is above. He doesn’t look scary.

And indeed, Friday has always gotten a bad rap. In the Middle Ages, people would not marry – or set out on a journey – on a Friday.

There are also some links between Christianity and an ill association with either Fridays or the number 13. Jesus was said to be crucified on a Friday. Seating 13 people at a table was seen as bad luck because Judas Iscariot, the disciple who betrayed Jesus, is said to have been the 13th guest at the Last Supper. Meanwhile, our word for Friday comes from Frigga, an ancient Scandinavian fertility and love goddess. Christians called Frigga a witch and Friday the witches’ Sabbath.

In modern times, the slasher-movie franchise Friday the 13th has helped keep friggatriskaidekaphobia alive.

The Friday the 13th slasher-movie franchise helped keep this day maintain its notoriety. Image via Wikimedia Commons.

In 2026, blame Thursday

In 2026, you can blame Thursday because the year started on a Thursday. Whenever a common year of 365 days starts on a Thursday, it’s inevitable that the months of February, March and November will start on a Sunday. And any month starting on a Sunday always has a Friday the 13th.

Of course, February has exactly four weeks in a non-leap year. So, for that reason, the days of the week have to match up with the same dates in both February and March during any common year. And in any year, the days of the week always fall on the same dates in both March and November. In short, because the year 2026 started on a Thursday, that means February, March and November all have to start on a Sunday and all must have a Friday the 13th.

The February-March-November Friday the 13th trilogy repeats …

How often does the February-March-November Friday the 13th trilogy repeat? More often than you might imagine! The last February-March-November Friday the 13th year happened 11 years ago, in 2015, for the second time in the 21st century (2001-2100). It will next happen eleven years from now, in 2037. After that, the following February-March-November Friday the 13th year will happen six years after 2037, in the year 2043.

A grand total of eleven February-March-November Friday the 13th years takes place in the 21st century (2001-2100):

2009, 2015, 2026, 2037, 2043, 2054, 2065, 2071, 2082, 2093 and 2099

And because the Gregorian calendar has a 400-year cycle, we also know the February-March-November Friday the 13th years will repeat exactly 400 years later in the 25th century (2401-2500):

2409, 2415, 2426, 2437, 2443, 2454, 2465, 2471, 2482, 2493 and 2499

Calendar for 2026

Calendar for the year 2026. There are 3 Friday the 13ths. They are in February, March and November. Calendar via EarthSky.

The rhyme and reason of the Friday the 13th cycle

Is there any rhyme and reason to the Friday the 13th cycle? Yes, it does make sense. Within the 21st century (2001-2100), note that the February-March-November Friday the 13th years repeat in 28-year cycles (going crosswise):

2009, 2037, 2065, 2093
2015, 2043, 2071, 2099
2026, 2054, 2082

Because the Gregorian calendar suppresses the leap year in 2100, the cycle is perturbed, meaning that all eleven February-March-November Friday the 13th years in the 22nd century (2101-2200) come four years earlier than in the 21st century:

2105, 2111, 2122, 2133, 2139, 2150, 2161, 2167, 2178, 2189 and 2195.

However, within the 22nd century (2101-2200), these Friday the 13th years also repeat in cycles of 28 years.

2105, 2133, 2161, 2189
2111, 2139, 2167, 2195
2122, 2150, 2178

The cycle is perturbed again in the 23rd century (2201-2300):

2201, 2229, 2257, 2285
2207, 2235, 2263, 2291
2218, 2246, 2274

And again in the 24th century (2301-2400):

2303, 2331, 2359, 2387
2314, 2342, 2370, 2398
2325, 2353, 2381

Friday-the-13th-year repetitions within 28-year cycle

Some of you, who might not yet be dazed by calendar numerology, may wonder if some formula governs how a given Friday the 13th year repeats within the 28-year cycle. The answer is a definite yes. Keep in mind that this particular February-March-November Friday the 13th year can only happen in a common year of 365 days, and when January 1 falls on a Thursday.

Therefore, if this threefold Friday the 13th year comes one year after a leap year, the days again match up with the dates in 6, 17 and 28 years afterward. For example, take the year 2009, which came one year after a leap year:

2009, 2015, 2026, 2037

However, if this triple Friday the 13th year falls two years after a leap year, the days and dates realign in 11, 17 and 28 years. Take this year, 2026, which takes place two years after a leap year:

2026, 2037, 2043, 2054

Finally, if this trio of Friday the 13ths happens three years after a leap year, the days recur with the same dates in 11, 22 and 28 years. The year 2015 happened three years after a leap year:

2015, 2026, 2037, 2043

It appears as though cycles of 372 and 400 years prevail over the long course of centuries. Take the year 2015, for instance:

2015 + 372 = 2387

2015 + 400 = 2415

The 372-year period is known as the Gregoriana eclipse cycle, which we elaborate about in our post: How often does a solar eclipse happen on the March equinox?.

Can three Friday the 13ths occur in a leap year?

What about three Friday the 13ths in a leap year? Yes, a leap year can harbor three Friday the 13ths (January 13 – April 13 – July 13) if the leap year starts on a Sunday, which last happened in 2012. However, given that this particular Friday the 13th year happens in a leap year, and a leap year only, it recurs only in periods of 28 years. So the last January-April-July Friday the 13th year happened in 1984, and will next happen in 2040.

If a common year starts on a Thursday, there are three Friday the 13ths; and if a leap year begins on a Sunday, there are three Friday the 13ths. So these are the two scenarios whereby three Friday the 13ths can occur in single calendar year.

Bottom line: From what we have been able to gather, the 400-year cycle displayed by Gregorian calendar features 59 years with three Friday the 13ths, consisting of 44 common years (February – March – November Friday the 13ths) and 15 leap years (January – April – July Friday the 13ths).

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The post 2026 has 3 Friday the 13ths. What are the odds? first appeared on EarthSky.

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Why are the Voyager spacecraft getting closer to Earth now?

View larger. | Both Voyager spacecraft are rushing away from Earth and into interstellar space. Yet for a portion of every year, both spacecrafts’ distances to Earth decrease. How is this possible? This chart shows the location of Voyager 2 as it leaves the solar system. Image via TheSkyLive.com. Used with permission.

Why are the Voyager spacecraft getting closer to Earth?

For a few months each year, the distances between the Voyager spacecraft and Earth actually decrease. You might know that both Voyager spacecraft were launched into space in the 1970s and visited the outer planets through the 1980s. They’ve been heading out of our solar system ever since. In 2012, Voyager 1 entered interstellar space. Then, in 2018, NASA announced that Voyager 2 had entered interstellar space, too. They are both headed outward, never to return to Earth. So, can they get closer?

The answer is that for a few months each year, Earth in its orbit moves toward the spacecraft faster than they’re moving away. Earth’s motion around the sun is faster than the motion of the Voyager spacecraft. Earth moves through space at a speed of 67,000 miles per hour (30 km/s). Voyager 1 moves at a speed of 38,000 miles per hour (17 km/s). Voyager 2 moves at a speed of 35,000 miles per hour (16 km/s).

So, for a portion of the year, Earth comes around the side of the sun and is speeding toward the spacecraft faster than they’re moving away. Therefore their distances to Earth are getting closer, if only temporarily. They never change their outward motion. It is we who change.

From this video, you can see the trajectory of the Voyager spacecraft as they leave Earth, encounter the outer planets (changing their trajectories), and then head in a straight line outward, out of the solar system.

Where are Voyager 1 and Voyager 2 now?

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A closer look at Voyager 2 in relation to Earth

Let’s look specifically at Voyager 2 as an example. Every year from late February to the beginning of June, Voyager 2 actually gets closer to Earth. We measure the distance between objects in space in astronomical units, or AU. This measurement is based on the distance between Earth and the sun, which is one AU.

On February 9, 2026, Voyager 2 was 143.09 AU from Earth. Then, Earth’s orbit began bringing us closer to Voyager 2 once again. The distance between us and Voyager 2 will continue to shrinking until early June when it’ll be 143.4 AU from Earth.

View larger. | This graph shows the distance of Voyager 2 from Earth from January 2020 through January 2030. It’s not a straight line because as Earth circles the sun. Earth’s faster speed means that for a part of every year, Voyager 2 and Earth temporarily get closer together. Image via TheSkyLive.com. Used with permission.

Read more: Voyager 1 location

Bottom line: The Voyager spacecraft are on a never-ending journey away from Earth. So, why do the distances between the spacecraft and Earth decrease for a few months every year? It’s because for a few months, Earth moves toward the spacecraft faster in its orbit around the sun than the spacecraft moves away from us.

The post Why are the Voyager spacecraft getting closer to Earth now? first appeared on EarthSky.

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View larger. | Both Voyager spacecraft are rushing away from Earth and into interstellar space. Yet for a portion of every year, both spacecrafts’ distances to Earth decrease. How is this possible? This chart shows the location of Voyager 2 as it leaves the solar system. Image via TheSkyLive.com. Used with permission.

Why are the Voyager spacecraft getting closer to Earth?

For a few months each year, the distances between the Voyager spacecraft and Earth actually decrease. You might know that both Voyager spacecraft were launched into space in the 1970s and visited the outer planets through the 1980s. They’ve been heading out of our solar system ever since. In 2012, Voyager 1 entered interstellar space. Then, in 2018, NASA announced that Voyager 2 had entered interstellar space, too. They are both headed outward, never to return to Earth. So, can they get closer?

The answer is that for a few months each year, Earth in its orbit moves toward the spacecraft faster than they’re moving away. Earth’s motion around the sun is faster than the motion of the Voyager spacecraft. Earth moves through space at a speed of 67,000 miles per hour (30 km/s). Voyager 1 moves at a speed of 38,000 miles per hour (17 km/s). Voyager 2 moves at a speed of 35,000 miles per hour (16 km/s).

So, for a portion of the year, Earth comes around the side of the sun and is speeding toward the spacecraft faster than they’re moving away. Therefore their distances to Earth are getting closer, if only temporarily. They never change their outward motion. It is we who change.

From this video, you can see the trajectory of the Voyager spacecraft as they leave Earth, encounter the outer planets (changing their trajectories), and then head in a straight line outward, out of the solar system.

Where are Voyager 1 and Voyager 2 now?

Don’t miss the next unmissable night sky event. Sign up to our free newsletter for daily night sky updates, as well as the latest science news.

A closer look at Voyager 2 in relation to Earth

Let’s look specifically at Voyager 2 as an example. Every year from late February to the beginning of June, Voyager 2 actually gets closer to Earth. We measure the distance between objects in space in astronomical units, or AU. This measurement is based on the distance between Earth and the sun, which is one AU.

On February 9, 2026, Voyager 2 was 143.09 AU from Earth. Then, Earth’s orbit began bringing us closer to Voyager 2 once again. The distance between us and Voyager 2 will continue to shrinking until early June when it’ll be 143.4 AU from Earth.

View larger. | This graph shows the distance of Voyager 2 from Earth from January 2020 through January 2030. It’s not a straight line because as Earth circles the sun. Earth’s faster speed means that for a part of every year, Voyager 2 and Earth temporarily get closer together. Image via TheSkyLive.com. Used with permission.

Read more: Voyager 1 location

Bottom line: The Voyager spacecraft are on a never-ending journey away from Earth. So, why do the distances between the spacecraft and Earth decrease for a few months every year? It’s because for a few months, Earth moves toward the spacecraft faster in its orbit around the sun than the spacecraft moves away from us.

The post Why are the Voyager spacecraft getting closer to Earth now? first appeared on EarthSky.

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Virga is rain that doesn’t reach the ground

Rain that doesn’t reach the ground

Have you seen clouds that are pouring rain … but the rain never reaches the ground? Meteorologists call this rain by the name virga. You see virga in places where the air is dry, and often warm. The rain evaporates as it falls, before hitting Earth. So you might see virga in a desert or at high altitudes, for example, in the western U.S. and Canadian prairies, the Middle East, Australia and North Africa. Virga isn’t rare. But it’s delicate and very beautiful. Maybe you’ve seen it lots of times, but never knew it had a name?

View at EarthSky Community Photos. | Ross Stone caught this virga – rain that doesn’t reach the ground – at Big Pine, California, on September 21, 2024. Good catch, Ross! Thank you.

Virga on radar

Sometimes, when you’re looking at your weather app, you might see what looks like rain or snow on the radar, but nothing is falling outside. Instead, look up at the clouds and see if you can spot virga. The radar is picking up precipitation in the air which is just not reaching the ground. As weather.gov says:

The radar isn’t lying, rather, the rain or snow is not hitting the ground. If you have a dry air mass in place in the low levels, sometimes rain cannot completely penetrate that dry layer before it evaporates.

This graphic gives you a better idea of how virga forms. The rainclouds higher up in the atmosphere are dropping rain, but as that moisture hits drier air below, it evaporates. So you might see radar indicating rain or snow, but nothing is reaching the ground. Image via weather.gov (public domain).

Do you want to learn to identify virga when you see it? Check out the photos on this page from our global EarthSky community. Once you acquaint yourself with the variations of virga, you’ll be able to spot it in your own sky. If you capture a photo of virga, submit it to us!

Can you identify virga?

Photos of virga from EarthSky’s community

View at EarthSky Community Photos. | Susan Jensen captured this image on May 6, 2024, in Washington. She wrote: “Late afternoon thunder with a few brief lightning flashes caught my attention! These were such beautiful virga clouds.” Thank you, Susan.

View at EarthSky Community Photos. | Helio C. Vital from Saquarema, Rio de Janeiro, Brazil, took this photo on December 17, 2023, and wrote: “The photo shows precipitation that is seen pending from a cloud and evaporating before reaching the ground (virga). The virga was backlit by the setting sun, that caused its strong reddish color.” Thank you, Helio!

View at EarthSky Community Photos. | Jennifer Browne captured this scene of virga and New Mexico’s Sangre de Cristo Mountains on October 23, 2023. Jennifer wrote: “Looking west from my home. The magic of Santa Fe sunsets.” Thank you, Jennifer! Look closely, and you’ll see the wispy undersides of the clouds. That’s virga.

Virga photos

View at EarthSky Community Photos. | Sandi Hryhor in Blairstown, New Jersey, caught this image of virga on March 26, 2022. Sandi wrote: “Taken at the Blairstown airport. It was completely overcast when we left our house 10 miles away, then some sun, then it hailed, and this sky greeted us when we arrived.” Thank you for sharing!

View at EarthSky Community Photos. | Jan Curtis took this photo on December 17, 2021, and wrote: “The lower levels of the atmosphere are very cold and moist. Lots of virga (ice crystals) are falling out of these thin cloud masses. Had this occurred in summer, severe weather is most likely later in the day. On this day, scattered convective snow shower occurred shortly after this mid-morning capture. An alternative cloud classification could be ‘altocumulus floccus clouds with virga’ but I believe these clouds were well below 6,000 feet [1,800 meters] above ground level.” Thank you, Jan!

More photos

View at EarthSky Community Photos. | Wells Shoemaker from Burr Point, Utah, took this photo on April 22, 2019, and wrote: “Late sun slashed through a crease in the clouds to illuminate the Wingate and Navajo cliffs above the Dirty Devil River … through a lace of virga.” Thank you, Wells!

Virga over West Texas. Image via EarthSky founder, Deborah Byrd.

Peter Lowenstein captured this scene from Mutare, Zimbabwe, on March 5, 2019. He wrote: “Some lingering clouds and a strange curtain of virga left over after a late afternoon shower produced a spectacular display just after the sun had set below the horizon.” Thank you, Peter!

View at EarthSky Community Photos. | Here’s a tricky one: a virga rainbow. Hazel Holby in Willows, California, captured this image on September 29, 2021. She wrote: “Can you tell me how this rainbow managed to form? Thank you and love your site!” Thank you, Hazel! Les Cowley of the website Atmospheric Optics said: “This is a broad bow and also of variable width. These suggest that it was made by virga or other small water droplets. The smaller the water drops, the broader the bow. When the drops get down to mist size, then we have a fogbow.” Thank you, Les!

Bottom line: Learn what virga is and how it forms, and see great photos to help you learn how to identify it yourself!

You deserve a daily dose of good news. For the latest in science and the night sky, click here to subscribe to our free daily newsletter.

The post Virga is rain that doesn’t reach the ground first appeared on EarthSky.

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Rain that doesn’t reach the ground

Have you seen clouds that are pouring rain … but the rain never reaches the ground? Meteorologists call this rain by the name virga. You see virga in places where the air is dry, and often warm. The rain evaporates as it falls, before hitting Earth. So you might see virga in a desert or at high altitudes, for example, in the western U.S. and Canadian prairies, the Middle East, Australia and North Africa. Virga isn’t rare. But it’s delicate and very beautiful. Maybe you’ve seen it lots of times, but never knew it had a name?

View at EarthSky Community Photos. | Ross Stone caught this virga – rain that doesn’t reach the ground – at Big Pine, California, on September 21, 2024. Good catch, Ross! Thank you.

Virga on radar

Sometimes, when you’re looking at your weather app, you might see what looks like rain or snow on the radar, but nothing is falling outside. Instead, look up at the clouds and see if you can spot virga. The radar is picking up precipitation in the air which is just not reaching the ground. As weather.gov says:

The radar isn’t lying, rather, the rain or snow is not hitting the ground. If you have a dry air mass in place in the low levels, sometimes rain cannot completely penetrate that dry layer before it evaporates.

This graphic gives you a better idea of how virga forms. The rainclouds higher up in the atmosphere are dropping rain, but as that moisture hits drier air below, it evaporates. So you might see radar indicating rain or snow, but nothing is reaching the ground. Image via weather.gov (public domain).

Do you want to learn to identify virga when you see it? Check out the photos on this page from our global EarthSky community. Once you acquaint yourself with the variations of virga, you’ll be able to spot it in your own sky. If you capture a photo of virga, submit it to us!

Can you identify virga?

Photos of virga from EarthSky’s community

View at EarthSky Community Photos. | Susan Jensen captured this image on May 6, 2024, in Washington. She wrote: “Late afternoon thunder with a few brief lightning flashes caught my attention! These were such beautiful virga clouds.” Thank you, Susan.

View at EarthSky Community Photos. | Helio C. Vital from Saquarema, Rio de Janeiro, Brazil, took this photo on December 17, 2023, and wrote: “The photo shows precipitation that is seen pending from a cloud and evaporating before reaching the ground (virga). The virga was backlit by the setting sun, that caused its strong reddish color.” Thank you, Helio!

View at EarthSky Community Photos. | Jennifer Browne captured this scene of virga and New Mexico’s Sangre de Cristo Mountains on October 23, 2023. Jennifer wrote: “Looking west from my home. The magic of Santa Fe sunsets.” Thank you, Jennifer! Look closely, and you’ll see the wispy undersides of the clouds. That’s virga.

Virga photos

View at EarthSky Community Photos. | Sandi Hryhor in Blairstown, New Jersey, caught this image of virga on March 26, 2022. Sandi wrote: “Taken at the Blairstown airport. It was completely overcast when we left our house 10 miles away, then some sun, then it hailed, and this sky greeted us when we arrived.” Thank you for sharing!

View at EarthSky Community Photos. | Jan Curtis took this photo on December 17, 2021, and wrote: “The lower levels of the atmosphere are very cold and moist. Lots of virga (ice crystals) are falling out of these thin cloud masses. Had this occurred in summer, severe weather is most likely later in the day. On this day, scattered convective snow shower occurred shortly after this mid-morning capture. An alternative cloud classification could be ‘altocumulus floccus clouds with virga’ but I believe these clouds were well below 6,000 feet [1,800 meters] above ground level.” Thank you, Jan!

More photos

View at EarthSky Community Photos. | Wells Shoemaker from Burr Point, Utah, took this photo on April 22, 2019, and wrote: “Late sun slashed through a crease in the clouds to illuminate the Wingate and Navajo cliffs above the Dirty Devil River … through a lace of virga.” Thank you, Wells!

Virga over West Texas. Image via EarthSky founder, Deborah Byrd.

Peter Lowenstein captured this scene from Mutare, Zimbabwe, on March 5, 2019. He wrote: “Some lingering clouds and a strange curtain of virga left over after a late afternoon shower produced a spectacular display just after the sun had set below the horizon.” Thank you, Peter!

View at EarthSky Community Photos. | Here’s a tricky one: a virga rainbow. Hazel Holby in Willows, California, captured this image on September 29, 2021. She wrote: “Can you tell me how this rainbow managed to form? Thank you and love your site!” Thank you, Hazel! Les Cowley of the website Atmospheric Optics said: “This is a broad bow and also of variable width. These suggest that it was made by virga or other small water droplets. The smaller the water drops, the broader the bow. When the drops get down to mist size, then we have a fogbow.” Thank you, Les!

Bottom line: Learn what virga is and how it forms, and see great photos to help you learn how to identify it yourself!

You deserve a daily dose of good news. For the latest in science and the night sky, click here to subscribe to our free daily newsletter.

The post Virga is rain that doesn’t reach the ground first appeared on EarthSky.

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