Crescent moon


Photo credit: Göran Strand

Photo credit: Göran Strand



If you’ve been watching the early evening sky, you know the moon has returned to it. It has appeared in a slim waxing crescent phase over these past evenings. Göran Strand of Sweden captured the crescent moon on Tuesday evening, November 25, 2014. Notice the glow over the unlit part of a crescent moon? It’s called earthshine, and it’s sunlight reflected from Earth’s day onto the moon’s surface.


A big thank you to Göran Strand for sharing his photo with us. You can see more beautiful photos by Göran Strand here






from EarthSky http://ift.tt/1vogRNu

Photo credit: Göran Strand

Photo credit: Göran Strand



If you’ve been watching the early evening sky, you know the moon has returned to it. It has appeared in a slim waxing crescent phase over these past evenings. Göran Strand of Sweden captured the crescent moon on Tuesday evening, November 25, 2014. Notice the glow over the unlit part of a crescent moon? It’s called earthshine, and it’s sunlight reflected from Earth’s day onto the moon’s surface.


A big thank you to Göran Strand for sharing his photo with us. You can see more beautiful photos by Göran Strand here






from EarthSky http://ift.tt/1vogRNu

Second of two lunar perigees in one month on November 27


Tonight’s moon and Mars appear in the evening sky as soon as darkness falls. On this date (November 27, 2014), for the second time this month, the moon swings to perigee – nearest point to Earth in its orbit. The moon last reached perigee on November 3. Because this is the second of two lunar perigees to occur in one calendar month, perhaps we could call the second one a blue moon perigee. Just kidding!


The November 27 perigee finds the moon at 369,827 kilometers (229,800 miles) distant. That’s nearly two thousand kilometers farther than the November 3 perigee, when the moon was 367,879 kilometers (228,589 miles) away.


In fact, the November 27 perigee ranks the most distant lunar perigee of the year. A more distant perigee won’t come again until September 13, 2017 (369,860 kilometers).


On sale! 25% off EarthSky lunar calendars. We’re giving thanks for all of you.


In November 2014, the moon reaches perigee twice: November 3 and November 27. Image credit: NASA

In November 2014, the moon reaches perigee twice: November 3 and November 27. Image credit: NASA



Perigees are nowhere close to equal throughout the year. The closest perigee of 2014 fell on August 10, when the moon swung within 356,896 kilometers of Earth. That’s nearly 13,000 kilometers closer than the farthest perigee of November 27 (369,827 kilometers).


Perigees aligning with the full moon and new moon bring about the year’s closest perigees. The two closest of 2014:



1. August 10, 2014: 356,896 kilometers (full moon)

2. January 1, 2014: 356,923 kilometers (new moon)



Perigees happening in the vicinity of the quarter moons bring about the year’s farthest perigees. The two farthest of 2014:



1. November 27, 2014: 369,827 kilometers (first quarter moon)

2. April 23, 2014: 369,765 kilometers (last quarter moon)



Moon at perigee and apogee 2001 to 2100


Today’s November 27 perigee happens at 23:11 Universal Time. At US time zones, that converts to 6:11 p.m. EST, 5:11 p.m. CST, 4:11 p.m. MST or 3:11 p.m. PST.


Bottom line: For the second time this month, the moon today swings to perigee – nearest point to Earth in its orbit. The moon is at 369,827 kilometers (229,800 miles) distant today, farther from Earth than it will be again until September 13, 2017.


EarthSky astronomy kits are perfect for beginners. Order today from the EarthSky store






from EarthSky http://ift.tt/1rxujK0

Tonight’s moon and Mars appear in the evening sky as soon as darkness falls. On this date (November 27, 2014), for the second time this month, the moon swings to perigee – nearest point to Earth in its orbit. The moon last reached perigee on November 3. Because this is the second of two lunar perigees to occur in one calendar month, perhaps we could call the second one a blue moon perigee. Just kidding!


The November 27 perigee finds the moon at 369,827 kilometers (229,800 miles) distant. That’s nearly two thousand kilometers farther than the November 3 perigee, when the moon was 367,879 kilometers (228,589 miles) away.


In fact, the November 27 perigee ranks the most distant lunar perigee of the year. A more distant perigee won’t come again until September 13, 2017 (369,860 kilometers).


On sale! 25% off EarthSky lunar calendars. We’re giving thanks for all of you.


In November 2014, the moon reaches perigee twice: November 3 and November 27. Image credit: NASA

In November 2014, the moon reaches perigee twice: November 3 and November 27. Image credit: NASA



Perigees are nowhere close to equal throughout the year. The closest perigee of 2014 fell on August 10, when the moon swung within 356,896 kilometers of Earth. That’s nearly 13,000 kilometers closer than the farthest perigee of November 27 (369,827 kilometers).


Perigees aligning with the full moon and new moon bring about the year’s closest perigees. The two closest of 2014:



1. August 10, 2014: 356,896 kilometers (full moon)

2. January 1, 2014: 356,923 kilometers (new moon)



Perigees happening in the vicinity of the quarter moons bring about the year’s farthest perigees. The two farthest of 2014:



1. November 27, 2014: 369,827 kilometers (first quarter moon)

2. April 23, 2014: 369,765 kilometers (last quarter moon)



Moon at perigee and apogee 2001 to 2100


Today’s November 27 perigee happens at 23:11 Universal Time. At US time zones, that converts to 6:11 p.m. EST, 5:11 p.m. CST, 4:11 p.m. MST or 3:11 p.m. PST.


Bottom line: For the second time this month, the moon today swings to perigee – nearest point to Earth in its orbit. The moon is at 369,827 kilometers (229,800 miles) distant today, farther from Earth than it will be again until September 13, 2017.


EarthSky astronomy kits are perfect for beginners. Order today from the EarthSky store






from EarthSky http://ift.tt/1rxujK0

Earth has its own Star-Trek-like invisible shield


Scientists have discovered an invisible shield roughly 7,200 miles above Earth that blocks so-called “killer electrons,” which can fry satellites and degrade space systems during intense solar storms. Illustration by Andy Kale, University of Alberta.

Scientists have discovered an invisible shield roughly 7,200 miles (11,600 km) above Earth that blocks so-called “killer electrons,” which can fry satellites and degrade space systems during intense solar storms. Illustration by Andy Kale, University of Alberta.



In the 1950s, James Van Allen made one of the first major discoveries of the space age when he and his team found Earth’s two Van Allen radiation belts. These doughnut-shaped rings high above Earth are filled with high-energy electrons and protons. They swell and shrink in response to incoming energy disturbances from the sun, as they protect Earth from space radiation and the effects of our sun’s activity. In 2013, Daniel Baker at the University of Colorado Boulder – who received his doctorate under Van Allen – led a team that used data from twin NASA probes to discover a third, transient storage ring between the inner and outer Van Allen radiation belts. Today, Baker announced that his team has found an “extremely sharp” boundary at the inner edge of the outer belt. This boundary layer is Earth’s own invisible Star-Trek-like shield, he said, in that it appears to block ultrafast electrons from moving deeper into Earth’s atmosphere. The journal Nature published a paper on this subject on November 26, 2014.


The newly found boundary layer is roughly 7,200 miles (11,600 km) above Earth’s surface. The Van Allen belts themselves extend up to 25,000 miles (40,000 km) high.

.

This new layer blocks what scientists sometimes call killer electrons, known to whip around Earth at near-light speed, threatening astronauts, frying satellites and degrading space systems during intense solar storms. What the killer electrons don’t do, however, is penetrate down to Earth’s surface. It was originally thought that these highly charged electrons slowly drifted downward into Earth’s upper atmosphere, where they were gradually wiped out by interactions with air molecules. But the impenetrable barrier seen by the twin Van Allen belt spacecraft stops the electrons before they get that far, said Baker, who added:



It’s almost like theses electrons are running into a glass wall in space.


Somewhat like the shields created by force fields on Star Trek that were used to repel alien weapons, we are seeing an invisible shield blocking these electrons.



Read more about the newly discovered invisible shield in the Van Allen belts from University of Colorado Boulder


Bottom line: Scientists led by Daniel Baker at the University of Colorado Boulder – using data from the twin Van Allen Probes launched by NASA in 2012 – studying Earth’s Van Allen belts have found an invisible shield that blocks ultrafast electrons from moving deeper into Earth’s atmosphere.






from EarthSky http://ift.tt/1vP6R24

Scientists have discovered an invisible shield roughly 7,200 miles above Earth that blocks so-called “killer electrons,” which can fry satellites and degrade space systems during intense solar storms. Illustration by Andy Kale, University of Alberta.

Scientists have discovered an invisible shield roughly 7,200 miles (11,600 km) above Earth that blocks so-called “killer electrons,” which can fry satellites and degrade space systems during intense solar storms. Illustration by Andy Kale, University of Alberta.



In the 1950s, James Van Allen made one of the first major discoveries of the space age when he and his team found Earth’s two Van Allen radiation belts. These doughnut-shaped rings high above Earth are filled with high-energy electrons and protons. They swell and shrink in response to incoming energy disturbances from the sun, as they protect Earth from space radiation and the effects of our sun’s activity. In 2013, Daniel Baker at the University of Colorado Boulder – who received his doctorate under Van Allen – led a team that used data from twin NASA probes to discover a third, transient storage ring between the inner and outer Van Allen radiation belts. Today, Baker announced that his team has found an “extremely sharp” boundary at the inner edge of the outer belt. This boundary layer is Earth’s own invisible Star-Trek-like shield, he said, in that it appears to block ultrafast electrons from moving deeper into Earth’s atmosphere. The journal Nature published a paper on this subject on November 26, 2014.


The newly found boundary layer is roughly 7,200 miles (11,600 km) above Earth’s surface. The Van Allen belts themselves extend up to 25,000 miles (40,000 km) high.

.

This new layer blocks what scientists sometimes call killer electrons, known to whip around Earth at near-light speed, threatening astronauts, frying satellites and degrading space systems during intense solar storms. What the killer electrons don’t do, however, is penetrate down to Earth’s surface. It was originally thought that these highly charged electrons slowly drifted downward into Earth’s upper atmosphere, where they were gradually wiped out by interactions with air molecules. But the impenetrable barrier seen by the twin Van Allen belt spacecraft stops the electrons before they get that far, said Baker, who added:



It’s almost like theses electrons are running into a glass wall in space.


Somewhat like the shields created by force fields on Star Trek that were used to repel alien weapons, we are seeing an invisible shield blocking these electrons.



Read more about the newly discovered invisible shield in the Van Allen belts from University of Colorado Boulder


Bottom line: Scientists led by Daniel Baker at the University of Colorado Boulder – using data from the twin Van Allen Probes launched by NASA in 2012 – studying Earth’s Van Allen belts have found an invisible shield that blocks ultrafast electrons from moving deeper into Earth’s atmosphere.






from EarthSky http://ift.tt/1vP6R24

Hangout with astrophysicists to discuss film Interstellar. Watch here



Today – November 26, 2014 – at 12 p.m. Pacific (2 Central, 3 Eastern, 2000 UTC), the Kavli Foundation will host a fun Google+ hangout on the science of the blockbuster film “Interstellar.”


Three astrophysicists will answer viewers’ questions about black holes, relativity and gravity, separating the movie’s science facts from its science fiction.


More details: http://bit.ly/11UGbQc


By the way, if the time for the Hangout has passed, come back to this space soon. We’ll be posting the video of the event as soon as it’s available.


Bottom line: Ever wanted to hang out with astrophysicists? Now is your chance. G+ hangout today to talk about the film Interstellar.






from EarthSky http://ift.tt/1vODMDG


Today – November 26, 2014 – at 12 p.m. Pacific (2 Central, 3 Eastern, 2000 UTC), the Kavli Foundation will host a fun Google+ hangout on the science of the blockbuster film “Interstellar.”


Three astrophysicists will answer viewers’ questions about black holes, relativity and gravity, separating the movie’s science facts from its science fiction.


More details: http://bit.ly/11UGbQc


By the way, if the time for the Hangout has passed, come back to this space soon. We’ll be posting the video of the event as soon as it’s available.


Bottom line: Ever wanted to hang out with astrophysicists? Now is your chance. G+ hangout today to talk about the film Interstellar.






from EarthSky http://ift.tt/1vODMDG

Using supermassive black holes to measure cosmic distances



“Eye of Sauron,” an actively growing supermassive black hole at the center of the galaxy called NGC 4151. Read more about this image



How do we know the distances across space? Astronomers start with an actual measurement of nearby stars via stellar parallax and use a stepping stone method to estimate the vast distances beyond the closest stars. It’s impressive, but the method is full of guesstimates, and thus cosmic distances are known to be uncertain. Now researchers from the Niels Bohr Institute at the University of Copenhagen say they’ve demonstrated that precise distances can be measured using supermassive black holes. The scientific journal Nature published their results, which they announced today (November 26, 2014).


To probe the usefulness of this method, the researchers used the central region of an active galaxy called NGC 4151. Its central region is the famous Eye of Sauron – not the one from Lord of the Rings, but a realm of space surely as formidable: a supermassive black hole at the center of NGC 4151, which we – at our great distance across space – see as still active. IN other words, unlike the dormant supermassive black hole at the center of our own Milky Way galaxy, the supermassive black hole in NGC 4151 still accretes – or accumulate – matter via gas clouds surrounding it. The researchers say it’s this process of accretion that makes it possible to measure the distance to the galaxy.


Darach Watson of the Dark Cosmology Center at the Niels Bohr Institute and study leader Sebastian Hönig, who now works at the University of Southampton in the U.K., worked together to obtain these results. Watson explained:



When the gas falls in towards the black hole, it is heated up and emits ultraviolet radiation. The ultraviolet radiation heats a ring of dust, which orbits the black hole at a large distance, and this heats the dust causing it to emit infrared radiation.


Using telescopes on Earth, we can now measure the time delay between the ultraviolet light from the black hole and the subsequent infrared radiation emitted from the dust cloud. The time difference is about 30 days, and because we know the speed of light, we can calculate the real physical distance between the black hole and the encircling dust.



He said that by combining the light from the two 10-meter Keck telescopes on Mauna Kea on Hawaii using a method called interferometry, his team was able make the two Keck telescopes act in a way that was equivalent to one telescope with a perfect 85-meter diameter mirror. According to their press release, that gave the two Keck telescopes:



… a hundred times better resolution than the Hubble Space Telescope — and allows them to measure the angle the dust ring makes in the sky, (about twelve millionth of a degree).



Then the researchers combined data about the angular size of the dust ring on the sky’s dome with the physical size of 30 light-days, to find the distance to the supermassive black hole in NGC 4151. Watson said:



We calculated the distance to be 62 million light-years. The previous calculations based on redshift (a change in the wavelength of the light due to the velocity of the object away from us) were between 13 million and 95 million light-years, so we have gone from a great deal of uncertainty to now being able to determine the precise distance. This is very significant for astronomical calculations of cosmic scale distances.



Here is the entire galaxy NGC 4151. It's located toward the constellation Canes Venatici. Image via David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration.

Here is the entire galaxy NGC 4151. It’s located in the direction to what we see as the constellation Canes Venatici. Image via David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration.



Watson said he and Sebastian Hönig were both



… thrilled with the results.


The process was almost magical. The most important thing about measuring distance is high precision — how accurate is the method. We knew that if we could get the uncertainty down to about 10 percent, it would be significant, but we had no idea that it was possible. When we first realized that we could carry out this measurement, we knew that the precision of the measurements of the angular size using interferometry and the physical size based on the time delay were both only about 30 percent. Normally, when you combine two such numbers, the accuracy of the ratio is worse, so we expected an overall accuracy of 40 percent or so. But that was not what happened. It turned out that the greatest uncertainty in both measurements was the distribution of the brightness across the dust ring. And it was the same in both measurements, so when we took the ratio, the uncertainties cancelled — simply disappeared. Sebastian Hönig, after making the first calculation, came to me and said: ‘You’ll never believe what the precision is, guess!’ Usually in science you fight so hard to get something to fit or work properly. But every so often — very rarely, something magical happens — it’s like a gift and everything just falls into place. That is what happened here.



The two Keck 10-meter (33 feet) telescopes. Image via NASA/JPL

The two Keck 10-meter (33 feet) telescopes. The black hole researchers used these two telescopes in a way that made them act equivalently to one telescope with a perfect 85-meter diameter mirror. Image via NASA/JPL



Bottom line: Niels Bohr Institute at the University of Copenhagen say they’ve demonstrated that precise distances can be measured using supermassive black holes. They used the famous “Eye of Sauron” an active supermassive black hole at the core of a distant galaxy called NGC 4151. Researchers measured the black hole’s distance at 62 million light-years.






from EarthSky http://ift.tt/1yhGOiw


“Eye of Sauron,” an actively growing supermassive black hole at the center of the galaxy called NGC 4151. Read more about this image



How do we know the distances across space? Astronomers start with an actual measurement of nearby stars via stellar parallax and use a stepping stone method to estimate the vast distances beyond the closest stars. It’s impressive, but the method is full of guesstimates, and thus cosmic distances are known to be uncertain. Now researchers from the Niels Bohr Institute at the University of Copenhagen say they’ve demonstrated that precise distances can be measured using supermassive black holes. The scientific journal Nature published their results, which they announced today (November 26, 2014).


To probe the usefulness of this method, the researchers used the central region of an active galaxy called NGC 4151. Its central region is the famous Eye of Sauron – not the one from Lord of the Rings, but a realm of space surely as formidable: a supermassive black hole at the center of NGC 4151, which we – at our great distance across space – see as still active. IN other words, unlike the dormant supermassive black hole at the center of our own Milky Way galaxy, the supermassive black hole in NGC 4151 still accretes – or accumulate – matter via gas clouds surrounding it. The researchers say it’s this process of accretion that makes it possible to measure the distance to the galaxy.


Darach Watson of the Dark Cosmology Center at the Niels Bohr Institute and study leader Sebastian Hönig, who now works at the University of Southampton in the U.K., worked together to obtain these results. Watson explained:



When the gas falls in towards the black hole, it is heated up and emits ultraviolet radiation. The ultraviolet radiation heats a ring of dust, which orbits the black hole at a large distance, and this heats the dust causing it to emit infrared radiation.


Using telescopes on Earth, we can now measure the time delay between the ultraviolet light from the black hole and the subsequent infrared radiation emitted from the dust cloud. The time difference is about 30 days, and because we know the speed of light, we can calculate the real physical distance between the black hole and the encircling dust.



He said that by combining the light from the two 10-meter Keck telescopes on Mauna Kea on Hawaii using a method called interferometry, his team was able make the two Keck telescopes act in a way that was equivalent to one telescope with a perfect 85-meter diameter mirror. According to their press release, that gave the two Keck telescopes:



… a hundred times better resolution than the Hubble Space Telescope — and allows them to measure the angle the dust ring makes in the sky, (about twelve millionth of a degree).



Then the researchers combined data about the angular size of the dust ring on the sky’s dome with the physical size of 30 light-days, to find the distance to the supermassive black hole in NGC 4151. Watson said:



We calculated the distance to be 62 million light-years. The previous calculations based on redshift (a change in the wavelength of the light due to the velocity of the object away from us) were between 13 million and 95 million light-years, so we have gone from a great deal of uncertainty to now being able to determine the precise distance. This is very significant for astronomical calculations of cosmic scale distances.



Here is the entire galaxy NGC 4151. It's located toward the constellation Canes Venatici. Image via David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration.

Here is the entire galaxy NGC 4151. It’s located in the direction to what we see as the constellation Canes Venatici. Image via David W. Hogg, Michael R. Blanton, and the Sloan Digital Sky Survey Collaboration.



Watson said he and Sebastian Hönig were both



… thrilled with the results.


The process was almost magical. The most important thing about measuring distance is high precision — how accurate is the method. We knew that if we could get the uncertainty down to about 10 percent, it would be significant, but we had no idea that it was possible. When we first realized that we could carry out this measurement, we knew that the precision of the measurements of the angular size using interferometry and the physical size based on the time delay were both only about 30 percent. Normally, when you combine two such numbers, the accuracy of the ratio is worse, so we expected an overall accuracy of 40 percent or so. But that was not what happened. It turned out that the greatest uncertainty in both measurements was the distribution of the brightness across the dust ring. And it was the same in both measurements, so when we took the ratio, the uncertainties cancelled — simply disappeared. Sebastian Hönig, after making the first calculation, came to me and said: ‘You’ll never believe what the precision is, guess!’ Usually in science you fight so hard to get something to fit or work properly. But every so often — very rarely, something magical happens — it’s like a gift and everything just falls into place. That is what happened here.



The two Keck 10-meter (33 feet) telescopes. Image via NASA/JPL

The two Keck 10-meter (33 feet) telescopes. The black hole researchers used these two telescopes in a way that made them act equivalently to one telescope with a perfect 85-meter diameter mirror. Image via NASA/JPL



Bottom line: Niels Bohr Institute at the University of Copenhagen say they’ve demonstrated that precise distances can be measured using supermassive black holes. They used the famous “Eye of Sauron” an active supermassive black hole at the core of a distant galaxy called NGC 4151. Researchers measured the black hole’s distance at 62 million light-years.






from EarthSky http://ift.tt/1yhGOiw

Another reason to be thankful for turkey


Photo credit: Brigham Young University

Photo credit: Brigham Young University



Here’s another reason to appreciate turkey this Thanksgiving: According to researchers, the biological machinery needed to produce a potentially life-saving antibiotic is found in turkeys.


Brigham Young University microbiologist Joel Griffitts and his team are exploring how the turkey-born antibiotic comes to be. Griffitts said:



Our research group is certainly thankful for turkeys. The good bacteria we’re studying has been keeping turkey farms healthy for years and it has the potential to keep humans healthy as well.



That’s because the good bacteria in turkeys, Strain 115 as scientists know it, produces an antibiotic called MP1 — a known killer that could target staph infections, strep throat, severe gastrointestinal diseases and roughly half of all infectious bacteria. This antibiotic, however, is not in widespread use because of its complex structure.


The research team has been working to identify exactly how Strain 115 makes this antibiotic, and how it manages to do so without killing itself.


Bottom line: Be thankful for turkeys this Thanksgiving! An antibiotic to target staph infections and strep comes from good bacteria in turkeys, say researchers.


Read more from Brigham Young University






from EarthSky http://ift.tt/1Cg8Ija

Photo credit: Brigham Young University

Photo credit: Brigham Young University



Here’s another reason to appreciate turkey this Thanksgiving: According to researchers, the biological machinery needed to produce a potentially life-saving antibiotic is found in turkeys.


Brigham Young University microbiologist Joel Griffitts and his team are exploring how the turkey-born antibiotic comes to be. Griffitts said:



Our research group is certainly thankful for turkeys. The good bacteria we’re studying has been keeping turkey farms healthy for years and it has the potential to keep humans healthy as well.



That’s because the good bacteria in turkeys, Strain 115 as scientists know it, produces an antibiotic called MP1 — a known killer that could target staph infections, strep throat, severe gastrointestinal diseases and roughly half of all infectious bacteria. This antibiotic, however, is not in widespread use because of its complex structure.


The research team has been working to identify exactly how Strain 115 makes this antibiotic, and how it manages to do so without killing itself.


Bottom line: Be thankful for turkeys this Thanksgiving! An antibiotic to target staph infections and strep comes from good bacteria in turkeys, say researchers.


Read more from Brigham Young University






from EarthSky http://ift.tt/1Cg8Ija

Video: Young volcanoes on the moon



Back in 1971, Apollo 15 astronauts orbiting the moon photographed something very odd. Researchers called it “Ina,” and it looked like the aftermath of a volcanic eruption.


There’s nothing odd about volcanoes on the moon, per se. Much of the moon’s ancient surface is covered with hardened lava. The main features of the “man in the moon,” in fact, are old basaltic flows deposited billions of years ago when the Moon was wracked by violent eruptions. The strange thing about Ina was its age.


Planetary scientists have long thought that lunar volcanism came to an end about a billion years ago, and little has changed since. Yet Ina looked remarkably fresh. For more than 30 years Ina remained a mystery.


Turns out, the mystery is bigger than anyone imagined. Using NASA’s Lunar Reconnaissance Orbiter, a team of researchers has found 70 landscapes similar to Ina. They call them “irregular mare patches” or IMPs for short.


Read more from NASA






from EarthSky http://ift.tt/1vihAi1


Back in 1971, Apollo 15 astronauts orbiting the moon photographed something very odd. Researchers called it “Ina,” and it looked like the aftermath of a volcanic eruption.


There’s nothing odd about volcanoes on the moon, per se. Much of the moon’s ancient surface is covered with hardened lava. The main features of the “man in the moon,” in fact, are old basaltic flows deposited billions of years ago when the Moon was wracked by violent eruptions. The strange thing about Ina was its age.


Planetary scientists have long thought that lunar volcanism came to an end about a billion years ago, and little has changed since. Yet Ina looked remarkably fresh. For more than 30 years Ina remained a mystery.


Turns out, the mystery is bigger than anyone imagined. Using NASA’s Lunar Reconnaissance Orbiter, a team of researchers has found 70 landscapes similar to Ina. They call them “irregular mare patches” or IMPs for short.


Read more from NASA






from EarthSky http://ift.tt/1vihAi1