A meteor hit the moon during the lunar eclipse...

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Maya Wei-Haas
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A dot of white light, seen here at left, marks the spot where a meteor hit the moon during a total lunar eclipse on January 20th.

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© Photograph by Christian Fröschlin

On Sunday, January 20, viewers across the Western Hemisphere were treated to the rusty hues of the decade's last “blood moon” eclipse. But as people across the planet watched the moon glow crimson, some lucky observers caught an unexpected delight: the flash of a space rock striking the lunar orb.

“It's a rare alignment of infrequent events,” says Justin Cowart, a Ph.D. candidate at Stony Brook University in New York. “A [meteoroid] about this size hits the moon about once a week or so,” he says. But if this event is confirmed, it may be the first time such an impact has been recorded during a lunar eclipse.


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© Photograph by Christian Fröschlin
A close-up of the darkened face of the "blood moon" shows the flash from the meteor impact.

An eagle-eyed viewer on Reddit spotted the potential impact during the eclipse and reached out to the r/space community to see if others could weigh in. The news spread quickly on social media, as people from across the path of totality posted their images and video of this tiny flicker of light.

Many scientists initially approached the claims with appropriate skepticism. After spotting the buzz on Twitter, “I was wondering if it was maybe a local effect, or maybe something with the camera,” says planetary scientist Sara Mazrouei of the University of Toronto.

Flashes of light from an impact are faint and short lived, making them easy to confuse with an errant pixel. But image after image showed the same thing: At 4:41 UT, when totality was just beginning, a tiny speck of light glinted south of the crater Byrgius, a nearly 55-mile-wide pockmark in the western part of the moon.

"They all seem to see the same bright pixel,” Mazrouei says. This confluence points strongly toward the flash of light actually being an impact.

“This is something that people all around the world didn't know that they were going to sign up for” says Noah Petro, a research scientist at NASA's Goddard Space Flight Center.


Watching for events

Backyard astronomers and star struck citizen scientists weren't the only ones watching. Jose Maria Madiedo, an astrophysicist at the University of Huelva in Spain, is co-director of the Moon Impacts Detection and Analysis System, MIDAS for short. He had been working overtime to get eight of the project's telescopes trained on the moon during the eclipse to watch for just such an event.

The MIDAS team usually scours the moon in search of faint flashes, the telltale signs of an impact, to learn about the array of space rocks that bombard our lunar companion. But most of these events are too dim to spot when the moon is full. The team does the bulk of their observing in the five days before and after a new moon. An eclipse, however, dulls the full moon's usually vibrant glow, providing one more rare opportunity to spot the tiny flashes of light.

So far, they hadn't successfully spotted an impact during an eclipse, but Madiedo didn't lose hope: “Something inside of me told me that this time would be the time.” And sure enough, his efforts paid off.

“I had a very nice reward,” he says.

Making an impact

Scientists say the next steps are gathering up the many observations to study the event in full detail, and hopefully capturing an image of the moon's new crater.

“The Earth and the moon are in such close proximity that observing the impacts on the moon can help us learn a lot more about the frequency of impacts on Earth,” explains Mazrouei, who recently authored a study detailing an ancient spike in large meteor bombardment on the moon, and thus on our planet.

Though Earth's atmosphere protects us from many of the smaller space rocks zooming through the solar system, incoming meteors can still affect the array of satellites zipping around the planet that are vital to keeping navigation, telecommunications, weather forecasting, and more humming along on the surface.

And seeing the aftermath of smaller impacts on airless worlds like the moon can help scientists learn about the effects of larger strikes on all kinds of worlds—including our own, Madiedo says.

“By knowing what happens with smaller impacts, you could know what could happen with larger impacts without really studying a large impact on Earth.”

Sweeping the moon

Finding the new crater on the already pockmarked surface of the moon will take some work, though. The spacecraft vital to this process is NASA's Lunar Reconnaissance Orbiter (LRO). Launched in 2009, the orbiter took up residence around our moon to study its surface in stunning detail. So far, it has recorded hundreds of changes to the lunar landscape, including more than two dozen new impact craters.

LRO even has history finding craters after initial reports of an impact flash. On March 17, 2013 researchers at NASA's Marshall Space Flight Center reported sighting a similar faint flicker of light on the moon. By comparing images of the moon's surface from LRO's trio of cameras before and after the event, scientists traced the debris streaks from the impact back to its associated crater.

For this latest event, the team responsible for LRO's cameras is not specifically targeting the crater in their sweeps over the moon. The orbiter essentially captures a random sampling of the moon's surface so scientists can calculate the average number of impacts over time, explains Petro, who is a project scientist for LRO. Specifically targeting the new crater would interfere with their statistical sampling.

Still, researchers can work to narrow down the new crater's location—and tease out more details about the impact itself—and then scour LRO data to see whether it passes over the right lunar section. Madiedo and his team are working to estimate the impact's energy and mass to assist in calculations of the crater's likely size and position. His initial estimates suggest that the space rock was about the size of a football, and that it left a crater around six miles across.

Stony Brook's Cowart is also trying to narrow down where the space rock struck using images from amateur astronomer Christian Fröschlin. He estimates that the crater lies around 29.47 south, 67.77 west. But accuracy is tricky; each pixel in the image represents an area about 2.5 miles across.

“So if I'm off by one pixel, then if we target that location, we can just totally miss the crater,” he says.

Regardless of whether the craft eventually captures the new crater, the series of events underscores the vital but often overlooked role social media can play in gathering data about natural phenomena, Petro says.

“I said going into the eclipse that this is really cool,” he adds. “This observation just reinforces how bloody cool it is.”


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Good Question...

Bad Answer...

I would imagine an ultra violent meteor collision on the moon's surface would kick up a debris cloud that would eject into the thin atmosphere ...and that ejection of material would be lit up by the ambient light as it goes beyond the curvature of the body it strikes.

You can be sure this story's writer ( Maya Wei-Haas ) is NOT a astrophysicist working for NASA...as she chose a random word as a descriptive adjective.

My 2 cents...

:stir pot:

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With no oxygen, how can a flash occur.
Same way the filament in an incandescent light bulb glows bright white - intense heat.
The circular path of the Earth around the sun has it/us moving about 66,000 MPH thru space. The moon moves with us.
Even something 'stationary' with respect to the sun's location would impact it (or us) at that speed. Meteors are usually moving thru space even faster, in addition to that.
The velocity alone of the impact is enough to heat rock to a bright white molten state even without an atmosphere.
 
Darn, you guys are way smarter than me. That got me thinking, a fiery comet can streak through an oxygen-free atmosphere, so my hypothesis must be incorrect. So much for that fire department dude that came into my junior high school, using that three colored wooden triangle telling us that a fire needs fuel, oxygen and heat!
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From NASA... https://www.nasa.gov/mission_pages/LADEE/news/lunar-atmosphere.html


Until recently, most everyone accepted the conventional wisdom that the moon has virtually no atmosphere. Just as the discovery of water on the moon transformed our textbook knowledge of Earth's nearest celestial neighbor, recent studies confirm that our moon does indeed have an atmosphere consisting of some unusual gases, including sodium and potassium, which are not found in the atmospheres of Earth, Mars or Venus. It's an infinitesimal amount of air when compared to Earth's atmosphere.

At sea level on Earth, we breathe in an atmosphere where each cubic centimeter contains 10,000,000,000,000,000,000 molecules; by comparison the lunar atmosphere has less than 1,000,000 molecules in the same volume. That still sounds like a lot, but it is what we consider to be a very good vacuum on Earth. In fact, the density of the atmosphere at the moon's surface is comparable to the density of the outermost fringes of Earth's atmosphere where the International Space Station orbits.

What is the moon's atmosphere made of ? We have some clues. The Apollo 17 mission deployed an instrument called the Lunar Atmospheric Composition Experiment (LACE) on the moon's surface. It detected small amounts of a number of atoms and molecules including helium, argon, and possibly neon, ammonia, methane and carbon dioxide. From here on Earth, researchers using special telescopes that block light from the moon's surface have been able to make images of the glow from sodium and potassium atoms in the moon's atmosphere as they are energized by the sun. Still, we only have a partial list of what makes up the lunar atmosphere. Many other species are expected.

We think that there are several sources for gases in the moon's atmosphere. These include high energy photons and solar wind particles knocking atoms from the lunar surface, chemical reactions between the solar wind and lunar surface material, evaporation of surface material, material released from the impacts of comets and meteoroids, and out-gassing from the moon's interior. But which of these sources and processes are important on the moon? We still don't know.

With the discovery of significant ice deposits at the moon's poles by NASA's Lunar CRater Observation and Sensing Satellite (LCROSS) and Lunar Reconnaissance Orbiter (LRO) missions, and the discovery of a thin scattering of water molecules in the lunar soil by the Chandrayaan X-ray Observatory, another fascinating possibility has captured researchers' interest. The moon's atmosphere may play a key role in a potential lunar water cycle, facilitating the transport of water molecules between polar and lower latitude areas. The moon may not only be wetter than we once thought, but also more dynamic.

One of the critical differences between the atmospheres of Earth and the moon is how atmospheric molecules move. Here in the dense atmosphere at the surface of Earth, the molecules' motion is dominated by collisions between the molecules. However the moon's atmosphere is so thin, atoms and molecules almost never collide. Instead, they are free to follow arcing paths determined by the energy they received from the processes described above and by the gravitational pull of the moon.

The technical name for this type of thin, collision-free atmosphere that extends all the way down to the ground is a "surface boundary exosphere." Scientists believe this may be the most common type of atmosphere in the solar system. In addition to the moon, Mercury, the larger asteroids, a number of the moons of the giant planets and even some of the distant Kuiper belt objects out beyond the orbit of Neptune, all may have surface boundary exospheres. But in spite of how common this type of atmosphere is, we know very little about it. Having one right next door on our moon provides us with an outstanding opportunity to improve our understanding.

Among the goals of the Lunar Atmosphere and Dust Environment Explorer (LADEE) are to determine the composition and structure of the tenuous lunar atmosphere and to understand how these change with time, and as external conditions vary. LADEE's measurements come at a key time: with increasing interest in the moon by a number of nations, future missions could significantly affect the natural composition of the lunar atmosphere.

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