Did this huge black hole swallow a star from the inside out?

A recently discovered black hole – found by the way it makes a nearby star wobble – is hard to square with our understanding of how these dark cosmic objects form. Image via NAOC/Chinese Academy of Sciences.

By Roberto Soria, Chinese Academy of Sciences

About 15,000 light-years away, in a distant spiral arm of the Milky Way, there is a black hole about 70 times as heavy as the sun.

This is very surprising for astronomers like me. The black hole seems too big to be the product of a single star collapsing, which poses questions for our theories of how black holes form.

Our team, led by Professor Jifeng Liu at the National Astronomical Observatories, Chinese Academy of Sciences, has dubbed the mysterious object LB-1.

What’s normal for a black hole?

Astronomers estimate that our galaxy alone contains about 100 million black holes, created when massive stars have collapsed over the past 13 billion years.

Most of them are inactive and invisible. A relatively small number are sucking in gas from a companion star in orbit around them. This gas releases energy in the form of radiation we can see with telescopes (mostly X-rays), often accompanied by winds and jets.

Until a few years ago, the only way to spot a potential black hole was to look for these X-rays, coming from a bright point-like source.

About two dozen black holes in our galaxy have been identified and measured with this method. They are different sizes, but all between about five and 20 times as heavy as the sun.

We generally assumed this was the typical mass of all the black hole population in the Milky Way. However, this may be incorrect; active black holes may not be representative of the whole population.

EarthSky 2020 lunar calendars are available! They make great gifts. Order now. Going fast!

The unusual black hole was spotted using the LAMOST telescope at Xinglong Observatory in China. Image via Chinese Academy of Sciences.

New tools bring an old idea to life

For our black hole search, we used a different technique.

We surveyed the sky with the Large sky Area Multi-Object fibre Spectroscopic Telescope (LAMOST) in northeast China, looking for bright stars that move around an invisible object. This let us detect the gravitational effect of the black hole, regardless of whether any gas moves from the star to its dark companion.

This technique was proposed by the British astronomer John Michell in 1783, when he first suggested the existence of dark, compact stars orbiting in a binary system with a normal star.

However, it has become practically feasible only with the recent development of large telescopes which let astronomers monitor the motion of thousands of stars at once.

John Michell (1724–1793) was the first scientist to predict the existence of compact stars from which light cannot escape. In 1783 he explained how to find them. Image via Philosophical Transactions of the Royal Society of London.

How we spotted LB-1

LB-1 is the first major result of our search with LAMOST. We saw a star eight times bigger than the sun, orbiting a dark companion about 70 times as heavy as the sun. Each orbit took 79 days, and the pair are about 1 1/2 times as far away from each other as Earth and the sun.

We measured the star’s motion by slight changes in the frequency of the light we detected coming from it, caused by a Doppler shift as the star was moving towards Earth and away from it at different times in its orbit.

We also did the same for a faint glow coming from hydrogen gas around the black hole itself.

Where did it come from?

How was LB-1 formed? It is unlikely that it came from the collapse of a single massive star: we think that any big star would lose more mass via stellar winds before it collapsed into a black hole.

One possibility is that two smaller black holes may have formed independently from two stars and then merged (or they may still be orbiting each other).

Another more plausible scenario is that one “ordinary” stellar black hole became engulfed by a massive companion star. The black hole would then swallow most of the host star like a wasp larva inside a caterpillar.

The discovery of LB-1 fits nicely with recent results from the LIGO-Virgo gravitational wave detectors, which catch the ripples in spacetime caused when stellar black holes in distant galaxies collide.

The black holes involved in such collisions are also significantly heavier (up to about 50 solar masses) than the sample of active black holes in the Milky Way. Our direct sighting of LB-1 proves that these overweight stellar black holes also exist in our galaxy.

Neutron stars (yellow) are as heavy as 1 to 2 suns. Black holes discovered from X-ray radiation (purple) have masses between 5 and 20 suns. Colliding black holes detected from gravitational waves each weigh up to about 50 suns. LB-1, detected from its orbital motion, has a mass of about 70. Image via LIGO-Virgo/Frank Elavsky/Northwestern/Universita Statale Milano.

The black hole family

Astronomers are still trying to quantify the distribution of black holes across their full range of sizes.

Black holes weighing between 1,000 and 100,000 suns (so-called intermediate-mass black holes) may reside at the heart of small galaxies or in big star clusters. The space-based Laser Interferometer Space Antenna (LISA) gravitational wave detector (scheduled for launch in 2034) will try to catch their collisions.

Black holes weighing a million to a few billion solar masses are already well known, in the nuclei of larger galaxies and quasars, but their origin is actively debated. We are still a long way away from a complete understanding of how black holes form, grow, and affect their environments, but we are making fast progress.

Roberto Soria, Professor, National Astronomical Observatories, Chinese Academy of Sciences

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

Bottom line: Astronomers say a recently discovered black hole in a distant spiral arm of the Milky Way might have swallowed a star from the inside out.

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

A recently discovered black hole – found by the way it makes a nearby star wobble – is hard to square with our understanding of how these dark cosmic objects form. Image via NAOC/Chinese Academy of Sciences.

By Roberto Soria, Chinese Academy of Sciences

About 15,000 light-years away, in a distant spiral arm of the Milky Way, there is a black hole about 70 times as heavy as the sun.

This is very surprising for astronomers like me. The black hole seems too big to be the product of a single star collapsing, which poses questions for our theories of how black holes form.

Our team, led by Professor Jifeng Liu at the National Astronomical Observatories, Chinese Academy of Sciences, has dubbed the mysterious object LB-1.

What’s normal for a black hole?

Astronomers estimate that our galaxy alone contains about 100 million black holes, created when massive stars have collapsed over the past 13 billion years.

Most of them are inactive and invisible. A relatively small number are sucking in gas from a companion star in orbit around them. This gas releases energy in the form of radiation we can see with telescopes (mostly X-rays), often accompanied by winds and jets.

Until a few years ago, the only way to spot a potential black hole was to look for these X-rays, coming from a bright point-like source.

About two dozen black holes in our galaxy have been identified and measured with this method. They are different sizes, but all between about five and 20 times as heavy as the sun.

We generally assumed this was the typical mass of all the black hole population in the Milky Way. However, this may be incorrect; active black holes may not be representative of the whole population.

EarthSky 2020 lunar calendars are available! They make great gifts. Order now. Going fast!

The unusual black hole was spotted using the LAMOST telescope at Xinglong Observatory in China. Image via Chinese Academy of Sciences.

New tools bring an old idea to life

For our black hole search, we used a different technique.

We surveyed the sky with the Large sky Area Multi-Object fibre Spectroscopic Telescope (LAMOST) in northeast China, looking for bright stars that move around an invisible object. This let us detect the gravitational effect of the black hole, regardless of whether any gas moves from the star to its dark companion.

This technique was proposed by the British astronomer John Michell in 1783, when he first suggested the existence of dark, compact stars orbiting in a binary system with a normal star.

However, it has become practically feasible only with the recent development of large telescopes which let astronomers monitor the motion of thousands of stars at once.

John Michell (1724–1793) was the first scientist to predict the existence of compact stars from which light cannot escape. In 1783 he explained how to find them. Image via Philosophical Transactions of the Royal Society of London.

How we spotted LB-1

LB-1 is the first major result of our search with LAMOST. We saw a star eight times bigger than the sun, orbiting a dark companion about 70 times as heavy as the sun. Each orbit took 79 days, and the pair are about 1 1/2 times as far away from each other as Earth and the sun.

We measured the star’s motion by slight changes in the frequency of the light we detected coming from it, caused by a Doppler shift as the star was moving towards Earth and away from it at different times in its orbit.

We also did the same for a faint glow coming from hydrogen gas around the black hole itself.

Where did it come from?

How was LB-1 formed? It is unlikely that it came from the collapse of a single massive star: we think that any big star would lose more mass via stellar winds before it collapsed into a black hole.

One possibility is that two smaller black holes may have formed independently from two stars and then merged (or they may still be orbiting each other).

Another more plausible scenario is that one “ordinary” stellar black hole became engulfed by a massive companion star. The black hole would then swallow most of the host star like a wasp larva inside a caterpillar.

The discovery of LB-1 fits nicely with recent results from the LIGO-Virgo gravitational wave detectors, which catch the ripples in spacetime caused when stellar black holes in distant galaxies collide.

The black holes involved in such collisions are also significantly heavier (up to about 50 solar masses) than the sample of active black holes in the Milky Way. Our direct sighting of LB-1 proves that these overweight stellar black holes also exist in our galaxy.

Neutron stars (yellow) are as heavy as 1 to 2 suns. Black holes discovered from X-ray radiation (purple) have masses between 5 and 20 suns. Colliding black holes detected from gravitational waves each weigh up to about 50 suns. LB-1, detected from its orbital motion, has a mass of about 70. Image via LIGO-Virgo/Frank Elavsky/Northwestern/Universita Statale Milano.

The black hole family

Astronomers are still trying to quantify the distribution of black holes across their full range of sizes.

Black holes weighing between 1,000 and 100,000 suns (so-called intermediate-mass black holes) may reside at the heart of small galaxies or in big star clusters. The space-based Laser Interferometer Space Antenna (LISA) gravitational wave detector (scheduled for launch in 2034) will try to catch their collisions.

Black holes weighing a million to a few billion solar masses are already well known, in the nuclei of larger galaxies and quasars, but their origin is actively debated. We are still a long way away from a complete understanding of how black holes form, grow, and affect their environments, but we are making fast progress.

Roberto Soria, Professor, National Astronomical Observatories, Chinese Academy of Sciences

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

Bottom line: Astronomers say a recently discovered black hole in a distant spiral arm of the Milky Way might have swallowed a star from the inside out.

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

What to look for on a 1st quarter moon

View at EarthSky Community Photos. | Tim Yacyshyn in Richmond, British Columbia, Canada captured this image on October 5, 2019. He wrote: “Taken exactly 12 hours after 1st quarter. As you can see, the famous Lunar X stands out quite prominently.” Thank you, Tim!

Read more: What is Lunar X?

Read more: December 3-4 brings 2019’s farthest 1st quarter moon

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View at EarthSky Community Photos. | Tim Yacyshyn in Richmond, British Columbia, Canada captured this image on October 5, 2019. He wrote: “Taken exactly 12 hours after 1st quarter. As you can see, the famous Lunar X stands out quite prominently.” Thank you, Tim!

Read more: What is Lunar X?

Read more: December 3-4 brings 2019’s farthest 1st quarter moon

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

December 3-4 brings 2019’s farthest 1st quarter moon

Above: Simulated bird’s-eye view of the Earth and moon at first quarter phase, as seen from the north side of the moon’s orbital plane.

This month’s first quarter moon comes on December 4, 2019, at 6:58 UTC. If you’re in the Americas, you can look for it on the evening of December 3. As viewed from the whole Earth, a 1st quarter moon is high up at sunset, looking like half a pie. There are a total of 12 first quarter moons in 2019, but this one counts as the most distant of them all, at 250,990 miles (403,929 km) from Earth. That’s because this December first quarter moon aligns more closely with lunar apogee – the moon’s farthest point from Earth in its monthly orbit – than any other first quarter moon in 2019.

First quarter moon: December 4 at 6:58 UTC
Lunar apogee: December 5 at 4:09 UTC

Dates for the moon’s phases in 2019 via Astropixels.

One fortnight (approximately two weeks) after the year’s farthest first quarter moon on December 4, it’ll be the year’s closest last quarter moon on December 19, at 4:57 UTC. That’s because this December last quarter moon gives us the year’s closest coincidence of last quarter moon with lunar perigee – the moon’s nearest point to Earth in its monthly orbit. This December last quarter moon sweeps to within 230,086 miles (370,287 km) of Earth.

Last quarter moon: December 19 at 4:57 UTC
Lunar perigee: December 18 at 20:30 UTC

That places the December 2019 last quarter moon nearly 21,000 miles (34,000 km) closer to Earth than the December 2019 first quarter moon.

Yet, seven first quarter moons previous to December 4 – on May 12, 2019 – it was the closest first quarter moon of the year, at 229,940 miles (370,053 km) away.

First quarter moon: May 12 at 1:12 UTC
Lunar perigee: May 13 at 21:53 UTC

The 13 lunar perigees and 13 lunar apogees in 2019. M = most distant perigee and apogee; m = closest perigee and apogee. Table via Astropixels

And seven last quarter moons before December 19 – on May 26, 2019 – it was the farthest last quarter moon of the year, at 251,113 miles (404,126 km) distant.

Last quarter moon: May 26 at 16:34 UTC
Lunar apogee: May 26 at 13:27 UTC

Once again, that’s a difference of about 21,000 miles (34,000 km) between the May 2019 first and last quarter moons.

To recap:

2019 May 12: year’s closest first quarter moon (229.940 miles or 370, 053 km)
2019 May 26: year’s farthest last quarter moon (251,113 miles or 404,126 km)

Seven lunar months later:

2019 Dec 04: year’s farthest first quarter moon (250,990 miles or 403,929 km)
2019 Dec 19: year’s closest last quarter moon (230,086 miles or 370,287 km)

For the fun of it, let’s look at the distances of the new/full moons that most closely align with lunar apogee/perigee in 2019:

2019 Feb 04: year’s farthest new moon (252,566 miles or 406,466 km)
2019 Feb 19: year’s closest full moon (221,736 miles or 356,846 km)

Seven lunar months later:

2019 Aug 30: year’s closest new moon (221,971 miles or 357,227 km)
2019 Sep 14: year’s farthest full moon (252,431 miles or 406,248 km)

That’s a difference of about 30,000 miles (50,000 km) between the apogee/perigee new/full moons – in stark contrast to the 21,000 miles (34,000 km) difference between apogee/perigee quarter moons.

Here’s a far moon/near moon comparison between the December 3, 2017 close full moon and 2017’s farthest full moon in June by Muzamir Mazlan at Telok Kemang Observatory, Port Dickson, Malaysia.

More impressive, perhaps, a new moon or full moon coinciding with perigee comes about 8,000 miles (13,000 km) closer to Earth than does a first or last quarter moon at perigee. Neil Degrasse Tyson, in an interview once claimed, “The distance to the moon – okay, the moon orbits us. It’s sometimes closer and it’s sometimes farther away. It has nothing to do with the phase.”

On the contrary, a quarter moon at perigee doesn’t sweep as close to Earth as a new or full moon at perigee; conversely, a quarter moon at apogee doesn’t swing as far out from Earth as a new or full moon at apogee. In other words, a quarter moon can never get as close to Earth as a supermoon (new or full moon near perigee) or as far away as a micro-moon (new or full moon near apogee).

For those brave souls wanting to know why quarter moons at perigee/apogee don’t get as close – or as far – as new and full moons at perigee or apogee, we provide an explanation below.

Diagram via Bedford Astronomy Club. The line connecting lunar perigee with lunar apogee defines the moon’s major axis. At (A) the major axis is pointing directly at the sun, maximizing the eccentricity of the moon’s orbit. At this elongated eccentricity, perigee is maximally close and apogee maximally distant, giving rise to a perigee new moon (supermoon) and an apogee full moon (micro-moon). Then, 3.5 lunar months (103 days) later, at (B), the moon’s major axis makes a right angle to the sun-Earth line. This minimizes the eccentricity, however, lessening the apogee distance yet increasing the perigee distance; and that’s why the quarter moons at perigee/apogee never get as close or as far from Earth as perigean/apogean new or full moons. Seven lunar months (206 days) after the major axis points directly at the sun at (A), it points toward the sun at (C) – except that it’s an apogee new moon (micro-moon) and perigee full moon (supermoon). Generally, the closest perigee comes at full moon and the farthest apogee at new moon.

Even though the year’s farthest first quarter moon comes on December 4, 2019. the moon actually reached its farthest point from Earth for the year on February 5, 2019.

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Above: Simulated bird’s-eye view of the Earth and moon at first quarter phase, as seen from the north side of the moon’s orbital plane.

This month’s first quarter moon comes on December 4, 2019, at 6:58 UTC. If you’re in the Americas, you can look for it on the evening of December 3. As viewed from the whole Earth, a 1st quarter moon is high up at sunset, looking like half a pie. There are a total of 12 first quarter moons in 2019, but this one counts as the most distant of them all, at 250,990 miles (403,929 km) from Earth. That’s because this December first quarter moon aligns more closely with lunar apogee – the moon’s farthest point from Earth in its monthly orbit – than any other first quarter moon in 2019.

First quarter moon: December 4 at 6:58 UTC
Lunar apogee: December 5 at 4:09 UTC

Dates for the moon’s phases in 2019 via Astropixels.

One fortnight (approximately two weeks) after the year’s farthest first quarter moon on December 4, it’ll be the year’s closest last quarter moon on December 19, at 4:57 UTC. That’s because this December last quarter moon gives us the year’s closest coincidence of last quarter moon with lunar perigee – the moon’s nearest point to Earth in its monthly orbit. This December last quarter moon sweeps to within 230,086 miles (370,287 km) of Earth.

Last quarter moon: December 19 at 4:57 UTC
Lunar perigee: December 18 at 20:30 UTC

That places the December 2019 last quarter moon nearly 21,000 miles (34,000 km) closer to Earth than the December 2019 first quarter moon.

Yet, seven first quarter moons previous to December 4 – on May 12, 2019 – it was the closest first quarter moon of the year, at 229,940 miles (370,053 km) away.

First quarter moon: May 12 at 1:12 UTC
Lunar perigee: May 13 at 21:53 UTC

The 13 lunar perigees and 13 lunar apogees in 2019. M = most distant perigee and apogee; m = closest perigee and apogee. Table via Astropixels

And seven last quarter moons before December 19 – on May 26, 2019 – it was the farthest last quarter moon of the year, at 251,113 miles (404,126 km) distant.

Last quarter moon: May 26 at 16:34 UTC
Lunar apogee: May 26 at 13:27 UTC

Once again, that’s a difference of about 21,000 miles (34,000 km) between the May 2019 first and last quarter moons.

To recap:

2019 May 12: year’s closest first quarter moon (229.940 miles or 370, 053 km)
2019 May 26: year’s farthest last quarter moon (251,113 miles or 404,126 km)

Seven lunar months later:

2019 Dec 04: year’s farthest first quarter moon (250,990 miles or 403,929 km)
2019 Dec 19: year’s closest last quarter moon (230,086 miles or 370,287 km)

For the fun of it, let’s look at the distances of the new/full moons that most closely align with lunar apogee/perigee in 2019:

2019 Feb 04: year’s farthest new moon (252,566 miles or 406,466 km)
2019 Feb 19: year’s closest full moon (221,736 miles or 356,846 km)

Seven lunar months later:

2019 Aug 30: year’s closest new moon (221,971 miles or 357,227 km)
2019 Sep 14: year’s farthest full moon (252,431 miles or 406,248 km)

That’s a difference of about 30,000 miles (50,000 km) between the apogee/perigee new/full moons – in stark contrast to the 21,000 miles (34,000 km) difference between apogee/perigee quarter moons.

Here’s a far moon/near moon comparison between the December 3, 2017 close full moon and 2017’s farthest full moon in June by Muzamir Mazlan at Telok Kemang Observatory, Port Dickson, Malaysia.

More impressive, perhaps, a new moon or full moon coinciding with perigee comes about 8,000 miles (13,000 km) closer to Earth than does a first or last quarter moon at perigee. Neil Degrasse Tyson, in an interview once claimed, “The distance to the moon – okay, the moon orbits us. It’s sometimes closer and it’s sometimes farther away. It has nothing to do with the phase.”

On the contrary, a quarter moon at perigee doesn’t sweep as close to Earth as a new or full moon at perigee; conversely, a quarter moon at apogee doesn’t swing as far out from Earth as a new or full moon at apogee. In other words, a quarter moon can never get as close to Earth as a supermoon (new or full moon near perigee) or as far away as a micro-moon (new or full moon near apogee).

For those brave souls wanting to know why quarter moons at perigee/apogee don’t get as close – or as far – as new and full moons at perigee or apogee, we provide an explanation below.

Diagram via Bedford Astronomy Club. The line connecting lunar perigee with lunar apogee defines the moon’s major axis. At (A) the major axis is pointing directly at the sun, maximizing the eccentricity of the moon’s orbit. At this elongated eccentricity, perigee is maximally close and apogee maximally distant, giving rise to a perigee new moon (supermoon) and an apogee full moon (micro-moon). Then, 3.5 lunar months (103 days) later, at (B), the moon’s major axis makes a right angle to the sun-Earth line. This minimizes the eccentricity, however, lessening the apogee distance yet increasing the perigee distance; and that’s why the quarter moons at perigee/apogee never get as close or as far from Earth as perigean/apogean new or full moons. Seven lunar months (206 days) after the major axis points directly at the sun at (A), it points toward the sun at (C) – except that it’s an apogee new moon (micro-moon) and perigee full moon (supermoon). Generally, the closest perigee comes at full moon and the farthest apogee at new moon.

Even though the year’s farthest first quarter moon comes on December 4, 2019. the moon actually reached its farthest point from Earth for the year on February 5, 2019.

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Orion the Hunter and the Milky Way

Never miss another full moon. Order your 2020 EarthSky Lunar Calendar today!

Tonight – or any December evening – find the famous constellation Orion the Hunter, and see the Milky Way running behind it. Orion is bright and can be seen from inside smaller cities. For the Milky Way, you’ll need a dark sky!

Throughout December, the constellation Orion is up by mid-evening; by that, we mean by midway between sunset and midnight. Like all the starry sky, Orion rises earlier each evening, and, by late December, Orion is seen at nightfall or early evening. That’s true for the Southern and Northern Hemispheres, by the way.

Orion is a summer constellation for the Southern Hemisphere.

For us in the Northern Hemisphere, because this constellation is up on our long December and January nights, we tend to associate Orion with the winter season.

Yuri Beletsky wrote from Chile: “a view from Atacama desert smile emoticon On the night Dec 13/14, 2015, we were very lucky to witness an amazing celestial event ! The “stars were falling from the sky” and it was a remarkable sight. I took this image at Carnegie Las Campanas observatory located in the south of Atacama desert in Chile. You can see numerous meteors as well as the Milky Way. One can easily recognize Orion constellation (although, for those who are in the Northern hemisphere it looks upside down). The telescopes on the foreground are the 6.5-m Magellans (Baade and Clay). I hope you’ll enjoy the view!” Thank you, Yuri!Visit Yuri on Facebook.

As seen from this hemisphere, after Orion rises, the three stars of Orion’s Belt jut pretty much straight up from the horizon. Look on either side of the Belt stars for two very bright stars. One is the reddish star Betelgeuse. The other is bright, blue-white Rigel.

Because so many people are familiar with Orion, this constellation is a great jumping off spot for finding the pathway of stars known as the Milky Way, assuming you have a dark sky. Given a dark sky, you can see this archway of stars running near the bright ruddy star Betelgeuse, as shown on the chart at the top of this post, and Yuri Beletsky’s photo above.

When we look at this band of luminescence, we’re viewing the galactic disk edgewise – the combined glow of billions of stars. You may know that – in the month of August – the Milky Way appears broad and bright during the evening hours. At that time of year, in the evening, all of us on Earth are gazing toward the center of the galaxy.

Now Earth has traveled in its orbit around the sun, and our evening sky is pointing out in a different direction. If you see the Milky Way near the constellation Orion this month, you might think it’s very faint in contrast to the August Milky Way. That’s because now we’re looking toward the galaxy’s outer edge, and there are fewer stars between us and intergalactic space.

Bottom line: You can find one of the most famous constellations – Orion the Hunter – plus see the Milky Way tonight.

Read More: Orion’s Belt and the Celestial Bridge

Easily locate stars and constellations during any day and time with EarthSky’s Planisphere.

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

Never miss another full moon. Order your 2020 EarthSky Lunar Calendar today!

Tonight – or any December evening – find the famous constellation Orion the Hunter, and see the Milky Way running behind it. Orion is bright and can be seen from inside smaller cities. For the Milky Way, you’ll need a dark sky!

Throughout December, the constellation Orion is up by mid-evening; by that, we mean by midway between sunset and midnight. Like all the starry sky, Orion rises earlier each evening, and, by late December, Orion is seen at nightfall or early evening. That’s true for the Southern and Northern Hemispheres, by the way.

Orion is a summer constellation for the Southern Hemisphere.

For us in the Northern Hemisphere, because this constellation is up on our long December and January nights, we tend to associate Orion with the winter season.

Yuri Beletsky wrote from Chile: “a view from Atacama desert smile emoticon On the night Dec 13/14, 2015, we were very lucky to witness an amazing celestial event ! The “stars were falling from the sky” and it was a remarkable sight. I took this image at Carnegie Las Campanas observatory located in the south of Atacama desert in Chile. You can see numerous meteors as well as the Milky Way. One can easily recognize Orion constellation (although, for those who are in the Northern hemisphere it looks upside down). The telescopes on the foreground are the 6.5-m Magellans (Baade and Clay). I hope you’ll enjoy the view!” Thank you, Yuri!Visit Yuri on Facebook.

As seen from this hemisphere, after Orion rises, the three stars of Orion’s Belt jut pretty much straight up from the horizon. Look on either side of the Belt stars for two very bright stars. One is the reddish star Betelgeuse. The other is bright, blue-white Rigel.

Because so many people are familiar with Orion, this constellation is a great jumping off spot for finding the pathway of stars known as the Milky Way, assuming you have a dark sky. Given a dark sky, you can see this archway of stars running near the bright ruddy star Betelgeuse, as shown on the chart at the top of this post, and Yuri Beletsky’s photo above.

When we look at this band of luminescence, we’re viewing the galactic disk edgewise – the combined glow of billions of stars. You may know that – in the month of August – the Milky Way appears broad and bright during the evening hours. At that time of year, in the evening, all of us on Earth are gazing toward the center of the galaxy.

Now Earth has traveled in its orbit around the sun, and our evening sky is pointing out in a different direction. If you see the Milky Way near the constellation Orion this month, you might think it’s very faint in contrast to the August Milky Way. That’s because now we’re looking toward the galaxy’s outer edge, and there are fewer stars between us and intergalactic space.

Bottom line: You can find one of the most famous constellations – Orion the Hunter – plus see the Milky Way tonight.

Read More: Orion’s Belt and the Celestial Bridge

Easily locate stars and constellations during any day and time with EarthSky’s Planisphere.

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

1st quarter moon is December 3-4

View at EarthSky Community Photos. | Our friend Dr Ski in the Philippines caught this photo as night came to his part of the world on November 4, 2019. He wrote: “The moon has reached 1st quarter and is visible on my side of the planet now.”

A first quarter moon rises around noon and sets around midnight. You’ll likely spot it in late afternoon or early evening, high up in the sky. At this moon phase, the moon is showing us precisely half of its lighted half. Or you might say that – at first quarter moon – we’re seeing half the moon’s day side.

We call this moon a quarter and not a half because it is one quarter of the way around in its orbit of Earth, as measured from one new moon to the next. Also, although a first quarter moon appears half-lit to us, the illuminated portion we see of a first quarter moon truly is just a quarter. We’re now seeing half the moon’s day side, that is. Another lighted quarter of the moon shines just as brightly in the direction opposite Earth!

And what about the term half moon? That’s a beloved term, but not an official one.

Read more: December 3-4 brings farthest 1st quarter moon

Read more: 4 keys to understanding moon phases

The lunar calendars are here! Get your 2020 lunar calendars today. They make great gifts. Going fast.

Lunar X and Lunar V appear when the moon is near its 1st quarter phase. They aren’t really Xs and Vs on the moon. They’re just high areas, catching sunlight, creating an example of pareidolia on the moon. Aqilla Othman in Port Dickson, Negeri Sembilan, Malaysia, caught them both in May of 2017. Notice that he caught Lunar X and Lunar V.

Here’s a closer look at Lunar X and Lunar V. Photo by Izaty Liyana in Port Dickson, Negeri Sembilan, Malaysia. What is Lunar X?

Tom Wildoner wrote: “One of my favorite areas to photograph on the moon near the 1st quarter! I captured this view of the sun lighting up the mountain range called Montes Apenninus. The moon was casting a nice shadow on the back side of the mountains. This mountain range is about 370 miles (600 km) long with some of the peaks rising as high as 3.1 miles (5 km).”

Bottom line: The moon reaches its 1st phase on December 4, 2019, at 06:58 UTC. If you’re in the Americas, you should look for it on the evening of December 3. As viewed from the whole Earth, a 1st quarter moon is high up at sunset, looking like half a pie.

Check out EarthSky’s guide to the bright planets.

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View at EarthSky Community Photos. | Our friend Dr Ski in the Philippines caught this photo as night came to his part of the world on November 4, 2019. He wrote: “The moon has reached 1st quarter and is visible on my side of the planet now.”

A first quarter moon rises around noon and sets around midnight. You’ll likely spot it in late afternoon or early evening, high up in the sky. At this moon phase, the moon is showing us precisely half of its lighted half. Or you might say that – at first quarter moon – we’re seeing half the moon’s day side.

We call this moon a quarter and not a half because it is one quarter of the way around in its orbit of Earth, as measured from one new moon to the next. Also, although a first quarter moon appears half-lit to us, the illuminated portion we see of a first quarter moon truly is just a quarter. We’re now seeing half the moon’s day side, that is. Another lighted quarter of the moon shines just as brightly in the direction opposite Earth!

And what about the term half moon? That’s a beloved term, but not an official one.

Read more: December 3-4 brings farthest 1st quarter moon

Read more: 4 keys to understanding moon phases

The lunar calendars are here! Get your 2020 lunar calendars today. They make great gifts. Going fast.

Lunar X and Lunar V appear when the moon is near its 1st quarter phase. They aren’t really Xs and Vs on the moon. They’re just high areas, catching sunlight, creating an example of pareidolia on the moon. Aqilla Othman in Port Dickson, Negeri Sembilan, Malaysia, caught them both in May of 2017. Notice that he caught Lunar X and Lunar V.

Here’s a closer look at Lunar X and Lunar V. Photo by Izaty Liyana in Port Dickson, Negeri Sembilan, Malaysia. What is Lunar X?

Tom Wildoner wrote: “One of my favorite areas to photograph on the moon near the 1st quarter! I captured this view of the sun lighting up the mountain range called Montes Apenninus. The moon was casting a nice shadow on the back side of the mountains. This mountain range is about 370 miles (600 km) long with some of the peaks rising as high as 3.1 miles (5 km).”

Bottom line: The moon reaches its 1st phase on December 4, 2019, at 06:58 UTC. If you’re in the Americas, you should look for it on the evening of December 3. As viewed from the whole Earth, a 1st quarter moon is high up at sunset, looking like half a pie.

Check out EarthSky’s guide to the bright planets.

Help EarthSky keep going! Please donate.

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

All you need to know: Geminid meteor shower in 2019

John Ashley in Glacier National Park, Montana, caught this amazing earthgrazer meteor on December 6, 2018. Earthgrazers are best seen in the evening hours. Watch for them during next week’s Geminid meteor shower! John said this one lasted approximately 4 seconds and left behind a glowing smoke train that lasted at least 24 minutes. He commented: “The meteor went dark just above Dusty Star Mountain, or ‘Iszika-kakatosi’ in Blackfeet, which translates to ‘smoking star.'” Cool! Thanks, John! Nikon D750, Rokinon 24mm lens @ f1.4, 30 sec, ISO 3200.

The Geminid meteor shower – always a highlight of the meteor year – will peak around the mornings of December 13 and 14, 2019, though under the light of a bright waning gibbous moon. The Geminids are a very reliable shower if you watch at the peak time of night (centered on about 2 a.m. for all parts of the globe) and if you watch in a dark sky. The meteors tend to be bold, white and quick. This shower favors Earth’s Northern Hemisphere, but it’s visible from the Southern Hemisphere, too. The curious rock comet called 3200 Phaethon is the parent body of this shower.

On a dark night, near the peak, you can often catch 50 or more meteors per hour. The bright moonlight this year is sure to diminish the numbers this year, but some Geminids should be bright enough to overcome the moonlit glare.

EarthSky lunar calendars are cool! They make great gifts. Order now. Going fast!

View larger. | Here’s a meteor and comet 46P/Wirtanen (upper left) from Jonny Hals in Elnesvågen, Norway. He posted this photo to EarthSky Facebook on December 12, 2018. Read about the comet.

Why are the Geminids best around 2 a.m.? It’s because that’s when the shower’s radiant point – the point in our sky from which the meteors seem to radiate – is highest in the sky. As a general rule, the higher the constellation Gemini the Twins climbs into your sky, the more Geminid meteors you’re likely to see. The Geminids’ radiant point is highest around 2 a.m.

Special equipment? None needed. Just find a dark, open sky and maybe bring a sleeping bag to keep warm. Plan to sprawl back in a hammock, lawn chair, pile of hay or blanket on the ground.

Lie down in comfort, and look upward.

Martin Marthadinata in Surabaya, East Java, Indonesia, caught this Geminid fireball in 2014, coming from the shower’s radiant point near the star Castor.

The Geminids radiate from near the bright star Castor in the constellation Gemini, in the east on December evenings, highest around 2 a.m. Learn more about the Geminids’ radiant point.

This Geminids’ radiant point nearly coincides with the bright star Castor in Gemini. That’s a chance alignment, of course, as Castor lies about 52 light-years away while these meteors burn up in the upper atmosphere, some 60 miles (100 km) above Earth’s surface.

Castor is noticeably near another bright star, the golden star Pollux of Gemini. It’s fun to spot them, but you don’t need to find a meteor shower’s radiant point to see these meteors.

Instead, meteors in annual showers appear in all parts of the sky. It’s even possible to have your back to the constellation Gemini and see a Geminid meteor fly by.

Jim Livingston in Custer, South Dakota, caught comet 46P/Wirtanen in the same field of view as a streaking meteor on December 9, 2018. See more images of comet Wirtanen. Canon 60D, Skywatcher 8″ reflector, CGX mount. Thanks, Jim!

When you’re meteor-watching, it’s good to bring along a buddy. Then two of you can watch in different directions. When someone sees one, call out “meteor!” This technique will let you see more meteors than one person watching alone will see.

Be sure to give yourself at least an hour of observing time. It takes about 20 minutes for your eyes to adapt to the dark.

Be aware that meteors often come in spurts, interspersed with lulls.

Painting of 1860 earthgrazer fireball by Frederic Edwin Church. Image via Wikimedia Commons.

Earthgrazers possible at early evening. Okay, we said you’ll likely see the most meteors at a time of night centered around 2 a.m. You won’t see as many Geminid meteors in early evening, when the constellation Gemini sits close to the eastern horizon.

But the evening hours are the best time to try to catch an earthgrazer meteor.

An earthgrazer is a slow-moving, long-lasting meteor that travels horizontally across the sky.

Earthgrazers are rarely seen but prove to be especially memorable, if you should be lucky enough to catch one.

Radar images of near-Earth asteroid 3200 Phaethon generated by astronomers at the Arecibo Observatory on December 17, 2017. The 2017 encounter was the closest the asteroid will come to Earth until 2093. Image via Wikipedia.

Geminid’s parent – 3200 Phaethon – is a “rock comet.” Every year in December, our planet Earth crosses the orbital path of an object called 3200 Phaethon, a mysterious body that is sometimes referred to as a rock comet. The debris shed by 3200 Phaethon crashes into Earth’s upper atmosphere at some 80,000 miles (130,000 km) per hour, to vaporize as colorful Geminid meteors.

In periods of 1.43 years, this small 5-kilometer (3-mile) wide asteroid-type object swings extremely close to the sun (to within one-third of Mercury’s distance), at which juncture intense thermal fracturing causes it to shed yet more rubble into its orbital stream.

There was big excitement about 3200 Phaethon in 2017, because this object was exceedingly nearby around nights of the Geminid meteor shower’s peak. It swept to within 6.4 million miles (10.3 million km, 26 lunar-distances) on December 16, 2017. In 2019, 3200 Phaethon is much farther away. Visit The Sky Live to know 3200 Phaethon’s present distance from the Earth and sun.

Read more: Mysterious rock comet 3200 Phaethon

Bottom line: The reliable Geminid meteor shower counts as one of the year’s best, but this year, in 2019, it takes place under moon-drenched skies.

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John Ashley in Glacier National Park, Montana, caught this amazing earthgrazer meteor on December 6, 2018. Earthgrazers are best seen in the evening hours. Watch for them during next week’s Geminid meteor shower! John said this one lasted approximately 4 seconds and left behind a glowing smoke train that lasted at least 24 minutes. He commented: “The meteor went dark just above Dusty Star Mountain, or ‘Iszika-kakatosi’ in Blackfeet, which translates to ‘smoking star.'” Cool! Thanks, John! Nikon D750, Rokinon 24mm lens @ f1.4, 30 sec, ISO 3200.

The Geminid meteor shower – always a highlight of the meteor year – will peak around the mornings of December 13 and 14, 2019, though under the light of a bright waning gibbous moon. The Geminids are a very reliable shower if you watch at the peak time of night (centered on about 2 a.m. for all parts of the globe) and if you watch in a dark sky. The meteors tend to be bold, white and quick. This shower favors Earth’s Northern Hemisphere, but it’s visible from the Southern Hemisphere, too. The curious rock comet called 3200 Phaethon is the parent body of this shower.

On a dark night, near the peak, you can often catch 50 or more meteors per hour. The bright moonlight this year is sure to diminish the numbers this year, but some Geminids should be bright enough to overcome the moonlit glare.

EarthSky lunar calendars are cool! They make great gifts. Order now. Going fast!

View larger. | Here’s a meteor and comet 46P/Wirtanen (upper left) from Jonny Hals in Elnesvågen, Norway. He posted this photo to EarthSky Facebook on December 12, 2018. Read about the comet.

Why are the Geminids best around 2 a.m.? It’s because that’s when the shower’s radiant point – the point in our sky from which the meteors seem to radiate – is highest in the sky. As a general rule, the higher the constellation Gemini the Twins climbs into your sky, the more Geminid meteors you’re likely to see. The Geminids’ radiant point is highest around 2 a.m.

Special equipment? None needed. Just find a dark, open sky and maybe bring a sleeping bag to keep warm. Plan to sprawl back in a hammock, lawn chair, pile of hay or blanket on the ground.

Lie down in comfort, and look upward.

Martin Marthadinata in Surabaya, East Java, Indonesia, caught this Geminid fireball in 2014, coming from the shower’s radiant point near the star Castor.

The Geminids radiate from near the bright star Castor in the constellation Gemini, in the east on December evenings, highest around 2 a.m. Learn more about the Geminids’ radiant point.

This Geminids’ radiant point nearly coincides with the bright star Castor in Gemini. That’s a chance alignment, of course, as Castor lies about 52 light-years away while these meteors burn up in the upper atmosphere, some 60 miles (100 km) above Earth’s surface.

Castor is noticeably near another bright star, the golden star Pollux of Gemini. It’s fun to spot them, but you don’t need to find a meteor shower’s radiant point to see these meteors.

Instead, meteors in annual showers appear in all parts of the sky. It’s even possible to have your back to the constellation Gemini and see a Geminid meteor fly by.

Jim Livingston in Custer, South Dakota, caught comet 46P/Wirtanen in the same field of view as a streaking meteor on December 9, 2018. See more images of comet Wirtanen. Canon 60D, Skywatcher 8″ reflector, CGX mount. Thanks, Jim!

When you’re meteor-watching, it’s good to bring along a buddy. Then two of you can watch in different directions. When someone sees one, call out “meteor!” This technique will let you see more meteors than one person watching alone will see.

Be sure to give yourself at least an hour of observing time. It takes about 20 minutes for your eyes to adapt to the dark.

Be aware that meteors often come in spurts, interspersed with lulls.

Painting of 1860 earthgrazer fireball by Frederic Edwin Church. Image via Wikimedia Commons.

Earthgrazers possible at early evening. Okay, we said you’ll likely see the most meteors at a time of night centered around 2 a.m. You won’t see as many Geminid meteors in early evening, when the constellation Gemini sits close to the eastern horizon.

But the evening hours are the best time to try to catch an earthgrazer meteor.

An earthgrazer is a slow-moving, long-lasting meteor that travels horizontally across the sky.

Earthgrazers are rarely seen but prove to be especially memorable, if you should be lucky enough to catch one.

Radar images of near-Earth asteroid 3200 Phaethon generated by astronomers at the Arecibo Observatory on December 17, 2017. The 2017 encounter was the closest the asteroid will come to Earth until 2093. Image via Wikipedia.

Geminid’s parent – 3200 Phaethon – is a “rock comet.” Every year in December, our planet Earth crosses the orbital path of an object called 3200 Phaethon, a mysterious body that is sometimes referred to as a rock comet. The debris shed by 3200 Phaethon crashes into Earth’s upper atmosphere at some 80,000 miles (130,000 km) per hour, to vaporize as colorful Geminid meteors.

In periods of 1.43 years, this small 5-kilometer (3-mile) wide asteroid-type object swings extremely close to the sun (to within one-third of Mercury’s distance), at which juncture intense thermal fracturing causes it to shed yet more rubble into its orbital stream.

There was big excitement about 3200 Phaethon in 2017, because this object was exceedingly nearby around nights of the Geminid meteor shower’s peak. It swept to within 6.4 million miles (10.3 million km, 26 lunar-distances) on December 16, 2017. In 2019, 3200 Phaethon is much farther away. Visit The Sky Live to know 3200 Phaethon’s present distance from the Earth and sun.

Read more: Mysterious rock comet 3200 Phaethon

Bottom line: The reliable Geminid meteor shower counts as one of the year’s best, but this year, in 2019, it takes place under moon-drenched skies.

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Orion, the Bull, the Pleiades and a meteor

View at EarthSky Community Photos. | Photo taken November 21, 2019 by Colin Chatfield of Saskatchewan, Canada.

Colin Chatfield in Saskatchewan caught this scene on the night of the Alpha Monocerotids meteor shower – November 21, 2019 – which was predicted to have a burst of meteors, but, sadly, didn’t live up to expectations. This meteor isn’t an Alpha Monocerotid. It’s not coming from the direction of the constellation Monoceros, the Unicorn, which is located below Orion (see chart below). It’s a good meteor, though! Colin wrote at his Instagram page:

Orion can be seen rising above the house with the Hyades [Face of the Bull in the constellation Taurus] above that, and the Pleiades at the top … It was a fairly decent night, for November at least. The wind picked up but it was still better than what we could have had. This is a new favorite spot for us to go shooting at, not too far east of Saskatoon. We were fortunate to have some auroras make an appearance too.

Colin doesn’t mention the sky’s brightest star – the Dog Star, Sirius – but it’s in his photo, too, behind the scaffolding of the old windmill. Sirius is an important star in locating the constellation Monoceros, radiant point of the Alpha Monocerotids shower.

Read more: Unicorn meteors proved elusive after all

Monoceros the Unicorn – which contained the radiant point of the Alpha Monocerotids – isn’t a prominent constellation. But it’s located near some of the most easy-to-spot stars in the night sky, including those of Orion the Hunter (look for Orion’s 3 Belt stars in a short, straight row) and the sky’s brightest star, the Dog Star Sirius. Chart via SkyandTelescope.com. Used with permission.

Bottom line: Photo of Orion, the Bull, the Pleiades and a meteor, taken on the night of the elusive Unicorn meteor shower – the Alpha Monocerotids – November 21, 2019.

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View at EarthSky Community Photos. | Photo taken November 21, 2019 by Colin Chatfield of Saskatchewan, Canada.

Colin Chatfield in Saskatchewan caught this scene on the night of the Alpha Monocerotids meteor shower – November 21, 2019 – which was predicted to have a burst of meteors, but, sadly, didn’t live up to expectations. This meteor isn’t an Alpha Monocerotid. It’s not coming from the direction of the constellation Monoceros, the Unicorn, which is located below Orion (see chart below). It’s a good meteor, though! Colin wrote at his Instagram page:

Orion can be seen rising above the house with the Hyades [Face of the Bull in the constellation Taurus] above that, and the Pleiades at the top … It was a fairly decent night, for November at least. The wind picked up but it was still better than what we could have had. This is a new favorite spot for us to go shooting at, not too far east of Saskatoon. We were fortunate to have some auroras make an appearance too.

Colin doesn’t mention the sky’s brightest star – the Dog Star, Sirius – but it’s in his photo, too, behind the scaffolding of the old windmill. Sirius is an important star in locating the constellation Monoceros, radiant point of the Alpha Monocerotids shower.

Read more: Unicorn meteors proved elusive after all

Monoceros the Unicorn – which contained the radiant point of the Alpha Monocerotids – isn’t a prominent constellation. But it’s located near some of the most easy-to-spot stars in the night sky, including those of Orion the Hunter (look for Orion’s 3 Belt stars in a short, straight row) and the sky’s brightest star, the Dog Star Sirius. Chart via SkyandTelescope.com. Used with permission.

Bottom line: Photo of Orion, the Bull, the Pleiades and a meteor, taken on the night of the elusive Unicorn meteor shower – the Alpha Monocerotids – November 21, 2019.

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