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Could Pluto hide liquid water far beneath its surface? Credit: NASA / JPL-Caltech

Adam Hadhazy, writer and editor for The Kavli Foundation, contributed this article to Space.com’s Expert Voices: Op-Ed & Insights.

After a journey lasting nine-and-a-half years, NASA’s New Horizons spacecraft finally reached the distant world of Pluto. The three-billion-mile expedition culminated with New Horizons sweeping a mere 7,800 miles (12,500 kilometers) above Pluto’s surface.

During its flyby, the probe obtained a treasure trove of scientific data, snapping by far the most detailed photographs ever taken of this mysterious object and its several moons. Instead of a cratered, barren orb — as some scientists expected — Pluto appears to be a startlingly dynamic world with soaring mountains and smooth plains of exotic ices. Information will continue pour in from New Horizons well into 2016 as the spacecraft transmits all of its data back to Earth. (Watch the hangout with Richard Binzel, Cathy Olkin and Michael Brown.)

On August 26, 2015, New Horizons team members Richard Binzel of the Kavli Institute for Astrophysics and Space Research at the Massachusetts Institute of Technology (MIT) and Cathy Olkin of the Southwest Research Institute (SRI), along with Kavli Prize Laureate Michael Brown of the California Institute of Technology, joined The Kavli Foundation for a live discussion. These planetary scientists answered questions about the mechanisms that might be shaping Pluto’s landscape  and what this strange new world can tell us about the other bodies at the solar system’s fringes.

Richard Binzel— is a professor of planetary sciences in the MIT department of Earth, Atmosphere and Planetary Sciences, and a member of the MIT Kavli Institute for Astrophysics and Space Research (MKI). He is a co-investigator on the New Horizons mission and has studied the Pluto-Charon system for 35 years. 

Cathy Olkin— is a principal scientist at the Southwest Research Institute (SWRI) and a deputy project scientist for the New Horizons mission. Her planetary science interests include the study of the icy surfaces and tenuous atmospheres of outer solar system worlds.

Michael Brown— is a professor of planetary astronomy at the California Institute of Technology and the 2012 Kavli Prize Laureate in Astrophysics for his research on the Kuiper Belt. His research specialty is the discovery and study of bodies at the edge of the solar system.

Below is a modified transcript of the discussion. Edits and changes have been made by the participants to clarify spoken comments recorded during the live webcast.

The Kavli Foundation: What has amazed each of you the most so far about the data from New Horizons?

Richard Binzel: I think it’s just seeing how dynamic Pluto is. As you said, we expected some smooth regions and some heavily cratered regions, but just to see the contrast of bright smooth regions right next to dark cratered regions, I think that’s the real surprise.

Cathy Olkin: One thing that stood out to me is this region we informally call Tombaugh Regio. It’s this large, bright, heart-shaped region. If people had predicted that there’d be a region the shape of a heart in the middle of the encounter flyby area, we would’ve never believed them. This region is scientifically very interesting. You see it’s very smooth and it has these polygonal shapes. It’s got interesting exotic ices on the surface there. It’s telling us a lot about what Rick was just talking about, about Pluto being a dynamic world. So, I would say Tombaugh Regio and just its presence there was very interesting.

Mike Brown: I just want to add that we’re all in complete agreement here of the things that we thought we’d see on Pluto. A lot of the times we say, “Everything’s a surprise,” and it’s not really true. There’s a lot of stuff that we knew ahead of time. We knew that these ices were on Pluto. We knew that there were dark regions and bright regions, and yet when you see them and you see that this Tombaugh Regio is this very concentrated smooth pile of these very volatile ices that should be evaporating at the equator, that’s just very strange and not what anybody would’ve expected at all.

R.B.: Well, I think that’s what we find when we go explore. It’s the complexity of nature. In fact, the reason why we go explore is because of the complexity of nature being revealed. As Mike said, we knew there were bright regions and dark regions, but seeing how complex they are and how little we understand about what makes them is now this really exciting frontier that we’re discovering.

TKF: Zooming out from Pluto’s surface to the atmosphere, New Horizons has revealed that Pluto is rapidly losing its atmosphere out to space because of its weak gravity. Yet Pluto has somehow maintained an atmosphere. How? 

C.O.: Pluto’s atmosphere is really large and extended, and you would expect that it would be escaping. So it has to be regenerated somehow. Those ices on the surface that we were talking about—they’ll sublimate and go from the solid form into a gaseous form, and then support the atmosphere. Of course over millions of years, you’ll have to have some source for resupply. There was a recent paper by Kelsi Singer and Alan Stern about potential sources of replenishing the nitrogen ice, which is the main predominant gas in the atmosphere. That paper proposed maybe there were sources internal to Pluto that were upwelling and providing ices coming up from the subsurface to the surface. Then that would sublimate and support that atmosphere. So that’s one theory for what’s supporting the atmosphere. [Lifting the Veil on Pluto’s Atmosphere ]

M.B.: Can I mention a more mundane potential explanation, which is what we thought for most of the past decade? We wrote a paper a few years ago suggesting that if you just had all these ices there to begin with at the abundances that we know exists in say, comets, that the loss rates on Pluto are such that you would still have the atmosphere there. So, I’m not convinced yet that the atmosphere needs replenishment through some sort of active mechanism. And one of the ways that we sort of show ourselves that we understand this process is by looking at all of the other objects out there in that region of the Kuiper Belt. The largest ones, which had the biggest inventories to begin with, still have those ices on them. They have the methane. They probably have the nitrogen and carbon monoxide. We can’t see those as well and as you get just a little bit smaller where they should have lost all of them to space, they don’t have them. So, it’s not clear to me that active rejuvenation is actually necessary.

R.B.: I think what’s going on there at Pluto is some of these seasonal effects. You have to realize Pluto’s in this eccentric orbit and so it goes as close to the sun as 30 AU and as far as 50 AU. [An “AU,” or astronomical unit, is the average distance between the Earth and the Sun.] So you could have times when it’s unseasonably warm on Pluto and it gets up to 60 Kelvin [-352 Fahrenheit] or so.

TKF: A heat wave!

R.B.: Exactly. So you can expect that there are times when it’s warmer and that some of the more volatile ices will go from the solid phase to the gas phase. And I think historically over time, just depending on what you think about loss rates, maybe Pluto’s lost a few kilometers of its upper layers. So, it’s not like all of Pluto evaporated. 

There are these other things going on, not only Pluto’s eccentric orbit. Pluto is tipped over in its orbit too, so there are some times when one of the poles is pointing Sun-on. Then Pluto has these century-long arctic summers, and that can be driving a lot of volatiles from the solid phase to the gas phase. There’s just a lot of complexity at Pluto that is just fantastic to try to unravel.

M.B.: I actually think that Rick’s point is the key point that didn’t get discussed very much during the flyby. Pluto is the most seasonally extreme world I think we’ve ever visited. So our instincts on what should and shouldn’t be there are often not very good. We need to really think about the seasons—what season it is right now, what season it’s just been and think about how all these ices move around and how everything moves around because of these seasons.

TKF: Looking again now at Pluto’s surface, what is throwing up these mountains ranges? What is smoothing out these plains? A viewer has a question if internal heat from Pluto is possibly contributing to all the geological activity that we’re witnessing and if so, what might be a source of that heat?

R.B.: The compositions of all the bodies in the solar system include radioactive elements. These include very long half-life elements whose ongoing decay continues to generate heat, even to the present day. You can pick up an ancient meteorite, like a carbonaceous chondrite and it’s generating heat at a very low rate. So, I think it’s not a surprise that any planetary body generates heat mainly from radioactive decay, from isotopes that are still active from the formation of the solar system. I think what’s tickling our thinking is it doesn’t take very much heat generation to start doing phase changes when phase changes become important at 40 Kelvin or 60 Kelvin. So I don’t think it takes anything special.

TKF: What do we think could be hiding or erasing so many of Pluto’s craters?

M.B.: I think the answer to that one is, again, what Rick brought up is that we have huge seasonal variation and the regions without craters are the regions of these very volatile ices that both can move around and can flow. They will easily either cover or evaporate craters. So the whole Tombaugh Regio region shouldn’t have craters in it. No one should be surprised not to see the craters there. I think that the most fascinating image that I’ve seen so far from New Horizons is that one that’s just on the edge of Tombaugh Regio, where you’re seeing the pile of ice on its edge and then the dark regions that are highly cratered on them. That part to me is what I would’ve expected to see to have been done by these seasonably variable ices.

C.O.: One thing I’d like to add. We have seasonal transport of volatiles and we do see craters in some of the terrains, but also in the Tombaugh Regio region, there’d be relaxation of the ices so that the historical record of the craters wouldn’t last as long. That’s another factor as well.

R.B.: Saying it another way Cathy, the nitrogen ice is relatively soft compared to water ice especially at these temperatures. So if you’re dominated by nitrogen, then you will get relaxation on short geologic time scales. 

TKF: That actually cues up a viewer question: What would it be like to try to ice skate on Pluto? We’re talking about exotic ices that we’re not at all used to dealing with in any manner here on Earth. What might happen if intrepid human explorers, many decades hence, tried to skate on Pluto’s otherworldly ices?

M.B.: We had a very long conversation on Twitter amongst many of us on exactly whether you could or could not ice skate on nitrogen ice or methane ice, because there are special properties of frozen water that allows ice skating and sliding on the ices. And water is a weird ice. Actually nitrogen, carbon monoxide and methane are normal ice—water’s the weird one. And so, we came to no conclusion about whether you could do it or not. There were arguments both directions. I’d be curious if you could go ice skating.

R.B.: Cathy, your colleague there in SwRI, Elliot Young, I thought wrote a paper on this and came somewhat to the conclusion with regard to skiing that you really needed that little “quick” water or liquid transformation right underneath your skis to go fast.

C.O.: That’s exactly right.

M.B.: Apparently, though, that idea for skiing and ice skating has been disproven? This is where the whole conversation on Twitter went. It’s not that melting that lets you ice skate, I’m now going to forget what the actual answer is, but that’s the one I learned in college and apparently that’s all wrong. 

R.B.: That’s what I always thought it was.

C.O.: Well, one thing I’d like to say about being able to go ice skating on Pluto is that it would be amazing. If we could go there and actually try it out. We could probably do that experiment somewhere else too.

R.B.: Let’s take volunteers!

C.O.: That’s right. I think that’s an interesting question and I really like the idea that we’re pushing the limits on our understanding. Pluto is such a different world than Earth. We have such different temperatures, different ices and so these questions that seem so obvious and you’d think, “Well, why isn’t the answer known?” That’s what science is. Let’s all go figure it out.

TKF: Could the fact that some of the surfaces on Pluto and its biggest moon Charon, which New Horizons also studied in detail, look so relatively new from a geological standpoint mean that these bodies formed later than the other bodies in the solar system?

R.B.: If you think about the formation of Pluto and Charon as a giant impact model, then it depends on the population density of the things that could do the impacting. I think it’s a stretch even assuming the current age of the solar system, which is 4.5 billion years. Mike certainly knows that population well.

M.B.: If the question is, “did the Pluto-Charon impact happen late?” it’s nearly impossible to even do it back four and a half billion years ago, because there weren’t that many objects available. So, trying to do it any more recently than that is just about impossible. But more importantly, as we were talking about earlier, I think the reasons that we’re not seeing the craters on Pluto are actually for all these reasons that we’ve been talking about. And we haven’t talked about Charon, but I think there are interesting reasons there, too. I think it’s not because the objects are young or because they have had major geological things happening. I think we’re not seeing craters everywhere because of these seasonal reasons and these interesting ices. 

TKF: What do we think the New Horizons findings might tell us about the other large bodies out there in the Kuiper Belt, like Eris and Makemake, and even farther out objects like Sedna?

M.B.: I’ve been thinking a lot about this one obviously, because these are the things that I study the most. And to me the New Horizons spacecraft is the best chance that we’ll get to explore all these objects in the outer solar system. We’re not going to send a spacecraft to any of the other ones anytime soon. So it’s been really fun to now filter my understanding of the outer solar system through what we’re seeing on New Horizons. 

What we see out there are bodies like Eris that are just about the same size as Pluto, yet a lot more massive. They must have different interiors, but their exteriors are very similar. If you could get to Eris, it’s going to have those same ices on it. Is it going to have a mound of nitrogen ice and carbon monoxide ice? I don’t know. Now I’d really like to know the answer to that question, but Eris has the same ices. 

Makemake is sort of just on the other side of Pluto, a little bit smaller, a little bit less massive, but still with big slabs of methane on the surface. And then there are objects that are a little smaller still, which my favorite one to think about these days is Quaoar, which I think of as about halfway between Pluto and Charon. Charon has got this icy cratered terrain with big flows on it. Pluto’s got all this methane and ices covering it. Quaoar has some of each and we’re now just beginning to think about what these things mean for this whole extended region. This is the exciting part for me.

C.O.: Pluto is, as Mike said, the object we got to see up close and it’s going to be a very long time before we see any of these other ones. And I can’t imagine that the one we chose to see up close is special or unique. We’re seeing a lot of dynamics, interesting processes, different things than we perhaps expected on the surface. But I don’t have any reason to believe that Pluto would be unique in the Kuiper Belt. So that’s telling us about what these other large bodies are like. 

R.B.: Again, I think it’s just the fundamentals of exploration. You go places where your intuition probably fails and I think in a large case our intuition has failed. Not that we got a lot of stuff wrong, it’s just the complexities. As a scientist, you just don’t let yourself go too far down that complexity chain, because there’s so many different complex outcomes that it doesn’t become meaningful. And then finally nature reveals what complex path it has chosen and it really is eye-opening for the entire solar system. So New Horizons is going to help us develop a new intuition for the rest of these other bodies. But kind of like siblings, if you have a lot of siblings, you know how different you are from your own siblings. I think each and every one of these objects is going to be their own world and have their own bragging rights.

TKF: The flip side of our last question—how can studying Pluto in fact tell us more about the formation of the inner worlds of the solar system, such as Earth?

C.O.: One thing that’s interesting about Pluto is that we believe that the Pluto and Charon binary system was formed by a giant impact, and that’s also how we believe the Earth and the Moon system were formed. So you’ve taken your sample size from one to two and now we’ve gotten to look closer up at Pluto and Charon, I’m hopeful that we’ll learn more about giant impact processes.

R.B.: You go out in the outer solar system and we think about the outer solar system being a deep freeze; the original chemistry of the solar system then hasn’t been altered in the way that the Earth has with all of its geologic geophysical properties or processes. We’re just going out and looking at frozen time capsules, the beginning of the solar system. So from a chemistry point of view, it’s fantastic. Comets are in that category too. I put them very high up in my chemistry curiosity box.

TKF: We were talking earlier about how Tombaugh Regio, the heart-shaped region on Pluto, might be a seasonal phenomenon basically. Is it possible to think that if we return to Pluto at a significantly later date that the heart would be gone?

R.B.: Great question. I want a Pluto orbiter! 

M.B.: For 250 years, so we can see Pluto the whole time!

R.B.: Exactly. The Rosetta mission, where the European Space Agency went to the Comet 67P/Churyumov–Gerasimenko last year and they’re following the comet as it comes closer to the Sun, is just like if you had a long-term, synoptic monitoring of Pluto. And now you start thinking about what are the capabilities of the planned successor to Hubble, the James Webb Space Telescope, to do that? What are the capabilities of even ALMA, this giant radio array in Chile to be able to do that? I think that we’re going into a new era of synoptic observations of Pluto that’s been ongoing for a number of decades, but that certainly now has a lot of renewed interest. 

C.O.: Also from ground-based astronomy, we knew for years that Pluto was brighter on one of its hemispheres, and now we know the details of what it looks like. We’ll be continuing to monitor Pluto. We’ll have to go back to our old toolbox of ground-based and Earth-based observing, but we’ll be able to look and see how the brightness of Pluto as it rotates changes. That will inform us about the evolution of the Tombaugh Regio.

M.B.: If you came back in 30 or 40 years, Tombaugh Regio would look different. I think we can guarantee that those volatiles will move around. But Tombaugh Regio looks so thick that I don’t think it’s going to come and go on a seasonal time scale. I thought so at first when it first looked like a bright spot. I was like, “There’s no way there could be that thick ice there,” it’s just so thick. Like Rick, I’ve been thinking about where are we going to get our next set of observations? And the telescopes that I think will actually do the next best job of being able to see this surface are going to be this generation of 30-meter telescopes, which will be able to see Hubble Space Telescope-like images that will at least tell you if that bright spot is still there. They won’t tell you if it looks like a heart anymore, or anything else, but if that spot is still there in 30 years, I think we will know from these telescopes on the ground and in space.

R.B.: And if I could get a shout out to a lot of our colleagues: There was a substantial effort to try to make ground-based observations in sync with the New Horizons mission. Particularly on June 29th, there was a stellar occultation that vast numbers of observers deployed to New Zealand and Australian for. The SOFIA airplane telescope was successful in observing that as well. So, as Cathy said, we’ve been monitoring Pluto for decades and there was this huge effort to try to link that data set—the long decades of ground-based with this instantaneous view sent by New Horizons. I think that’s really going to pay off as we go forward. It’s going to pay off in answering exactly these kind of questions of now that we’ve seen Pluto, what changes can we detect going on now and for the decades ahead?

C.O.: Even just looking at the imagery that we already have down from this spacecraft, you can see evidence that the extent of Tombaugh Regio was different in the past. You can see bright regions in what looks to be like craters. In the bottom of the craters, you could imagine maybe Tombaugh Regio was extended further and then had receded. Or maybe perhaps it’s seasonal volatile transport and the volatiles are condensing there on Tombaugh Regio because it’s a lower terrain, lower altitude. I think there’s evidence that Tombaugh Regio had a different boundary in the past. 

TKF: Much more data will be coming back from New Horizons well into next year. What images and measurements are you most eagerly awaiting?

C.O.: There’s so much stuff onboard New Horizons that I just cannot wait to see. One of the things that I’m really looking forward to the most is our high-resolution scan that we took of Pluto with the Alice instrument. Its part of the Ralph instrument and it’s the infrared spectrometer. It’s going to be able to get high-resolution infrared spectroscopy across the surface of Pluto to map those ices and see what other minor species might be there that we couldn’t detect when we were looking at Pluto as a point of light from Earth or using Earth-based observations. That’s one I’m really looking forward to getting down.

R.B.: There’s a very clever observation that we’re after. When New Horizons went by Pluto, we turned it around and looked at Pluto using moon’s Charon light to illuminate the dark side of Pluto, in fact the southern hemisphere of Pluto that’s now in arctic winter. We’ll be able to see that south polar cap, and I will really be interested to see the extent of that.

M.B.: I’m excited about both of those things that you guys talked about and the one that we keep on avoiding mention of, but the images of Charon. I want to see those global, high-resolution, uncompressed images of Charon and really see where these big cracks have flowed out onto the surface. Maybe we get some composition data on what those flows might have been. I think that is going to tell us a lot about the mid-sized objects that are throughout the Kuiper Belt. There are many, many Charon-like objects out there, and I’d like to learn more about all of them by looking at those images.

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TKF: Something that we’ve alluded to in our conversation is just how fundamentally different Pluto is from Earth. When we think of “geology,” we think of everyday stuff like hard rock underfoot and water-ice. Way out in the solar system by Pluto, though, there is less rock to begin with, and it’s so cold that ice essentially takes over the duties of rock here in the inner solar system. How will we understand these new “ice worlds” versus our “rocky world?”?

M.B.: I’ll take on that question, but I’m going to flip it and say how similar they are. We think of this as strangely exotic that we have ice instead of rock. But as long as you just think of rock as the hard material underground that’s frozen, the rock under our feet could be magma, but it’s frozen, so you get many of the same things. I was talking about those flows on Charon. I think of them as big volcanic outbursts on Charon, and what are the volcano’s outbursting? Well, it’s magma, but on Charon what is magma? Magma is the melted rock, which means water. So, there are these water flows on Charon that if you could imagine them when they happened, if you’ve ever seen a lava flow on the Earth, it’s this beautiful site where you see the molten lava coming in, starting to freeze out on the surface and continue to flow. The same sort of thing would happen. 

With the ice on Charon, you would get these very similar processes. You would build these structures, like big volcanic dykes. And then on Pluto we talk about the ices, the Tombaugh Regio ices there, which are the nitrogen and carbon monoxide methane ices. They are what we think of as snow around here. It doesn’t work perfectly, but you can transfer some of your thinking in that direction and think of Pluto and Earth as more similar in some ways than totally different . . . except they’re totally different!

C.O.: I’d like to add to that, just thinking about Pluto’s atmosphere, because I often think about it as similar and different once again. Both Earth’s atmosphere and Pluto’s atmosphere are predominantly composed of nitrogen, but Earth’s atmosphere is a lot more dense than Pluto’s atmosphere, which is about 100,000 times less dense. That causes different processes to be going on. Then we also have hazes. You can have a hazy day on Earth.

M.B.: Los Angeles!

C.O.: Yes, Los Angeles, that’s right. And wildfires have made it kind of hazy here in Colorado, where I am. There’s hazes in Pluto’s atmosphere that we saw, and it was a really breathtaking image, the one where we were looking back at Pluto from the spacecraft and seeing the extent of those hazes. How they’re formed and what they’re made of are different, but there’s a lot of analogous things to think about when you’re comparing Earth and Pluto.

Follow all of the Expert Voices issues and debates — and become part of the discussion — on Facebook, Twitter and Google+. The views expressed are those of the author and do not necessarily reflect the views of the publisher. This version of the article was originally published on Space.com.

The far side of the moon, often mistakenly called the “dark side” though it receives just as much sunlight as the near side, as imaged by NASA’s Lunar Reconnaissance Orbiter. Credit: NASA/Goddard/Arizona State University

Sunday’s rare “supermoon” total lunar eclipse has prompted greater discussion of the moon — and those discussions sometimes involve persistent lunar myths.

Some of these myths are simple misconceptions, such as the notion that the moon is perfectly round (it’s not), or that it lacks gravity (all celestial bodies exert some gravitational force). Other myths are more conspiracy-oriented, such as the idea that the Apollo moon landings were faked.

Below you can read about a few of the most prevalent lunar myths. The discussion may give you something to think about Sunday evening (Sept. 27) while watching the first supermoon lunar eclipse — so named because it will occur when the moon appears abnormally large and bright in the sky — since 1982, and the last until 2033. [How to See Sunday’s Supermoon Lunar Eclipse]

Myth 1: The supermoon eclipse heralds the end of the world

Sunday’s supermoon eclipse is the last of the current lunar tetrad, a series of four lunar eclipses that have occurred over the last 18 months. Some people have regarded the tetrad as a sign of the end of the world. This dubious claim was made in a recent book about four “blood moons,” a term rarely used by astronomers.

While eclipse tetrads are rare, they have taken place in the past, and will continue to occur in the future. A previous tetrad occurred in 2003 and 2004, and such groupings will occur seven more times in the current century.

“Throughout human history, people have always thought that things in the sky that they didn’t understand were either signs of apocalypse or good luck, or the gods were angry or pleased,” Noble said. “Lunar tetrads are simply the result of orbital dynamics and geometry — no need to invoke the supernatural or the end of the world.” 

Myth 2: The moon grows larger during moonrise

I’ve actually had arguments — er, enthusiastic discussions — with people regarding whether or not the moon moves closer to the Earth as it rises, making it appear larger than normal. While the moon does vary in distance from the Earth during its month-long orbit, the differences aren’t significant during a single trek across the sky.

Rather, the reason the moon looks larger near the horizon is due to an optical effect known as the Ponzo illusion.

“The human mind judges an object’s size based on its background,” Noble said. “We think of things on the horizon as being further away from us, so our brains fool us into thinking the moon must be bigger.”

The moon’s orbit is slightly elliptical, so its distance from Earth varies from approximately 222,000 miles (357,000 kilometers) to 252,000 miles (406,000 km) over the course of a month. During the lunar eclipse this weekend, the moon will be at perigee, the closest point to Earth, at which point Noble said it appears about 14 percent bigger and up to 30 percent brighter than the moon at its most distant.

“If it is a clear night, this moon, pre- and post-eclipse, will be about 15 percent brighter than the average moon,” Noble said. [‪Amazing Supermoon Photos: Biggest Full Moon of 2014]

Myth 3: The moon has a ‘dark side’

As the moon orbits Earth, it keeps one face perpetually turned toward the planet. This fact has prompted some to refer to the distant lunar hemisphere as the “dark side” of the moon, as popularized by a 1973 Pink Floyd album of the same name. However, this label is false, because during the new-moon phase, when the surface pointed toward Earth is all but unseen, the “dark” hemisphere is pointed toward the sun.

While lunar “back side” is acceptable, “far side” is the preferred term among scientists, said Sarah Noble, who served as program scientist for NASA’s Lunar Atmosphere and Dust Environment Explorer (LADEE) mission, which ended in April 2014 when the orbiter intentionally crashed into the surface of the moon.

Several missions have orbited the moon and provided a great deal of information about the far side. Most recently, NASA’S Lunar Reconnaissance Orbiter (LRO) has obtained imagery and topography of the entire moon, including the far side.

“We know quite a lot about the lunar far side,” Noble told Space.com by email.

Myth 4: The moon has no gravity

Freewheeling astronauts on the moon may give observers the idea that Earth’s companion has no gravity, but that would be false. Everything with mass has gravity, and the strength of an object’s gravitational field is determined by its mass.

The moon is much less massive than Earth; the Apollo astronauts who explored its surface experienced gravity just 17 percent as strong as that of their home planet.

Smaller objects, such as asteroids and Mars’ tiny moons Phobos and Deimos, have much weaker gravity still.

“You wouldn’t really land on them; it would be more like docking with them,” Noble said of these bantam bodies. Explorers would have to anchor to them, or hover nearby.

“Likewise, astronauts would probably remain tethered to the ship, in case they accidentally launch themselves off the surface,” Noble added. “I imagine that exploring would look more like rock climbing than hiking, with astronauts scrambling around using their hands as much as their feet to navigate.” [How Sending Humans to an Asteroid Would Work (Infographic)] 

Moon Master: An Easy Quiz for Lunatics

For most of human history, the moon was largely a mystery. It spawned awe and fear and to this day is the source of myth and legend. But today we know a lot about our favorite natural satellite. Do you?

0 of 10 questions complete

Moon Master: An Easy Quiz for Lunatics

For most of human history, the moon was largely a mystery. It spawned awe and fear and to this day is the source of myth and legend. But today we know a lot about our favorite natural satellite. Do you?

0 of questions complete

Myth 5: ‘The man in the moon’ 

Many people claim to see “the man in the moon” on the lunar surface. On the near side, lava flowed from volcanoes that were active from one to four billion years ago into craters and basins created by impacts, forming dark regions called “mare.”

“Because of a psychological phenomenon called pareidolia, humans tend to interpret patters as familiar things, particularly faces, so we see the man in the moon,” Noble said.

She pointed out that other cultures see a rabbit rather than a human face, inspiring the name for the recent Chinese lander, Yutu, which means “Jade Rabbit.” The rabbit was mentioned during the Apollo 11 landing in 1969, when the following conversation took place between mission control in Houston and Michael Collins, the astronaut who remained in the lunar orbiter:

“Houston: Among the large headlines concerning Apollo this morning, there’s one asking that you watch for a lovely girl with a big rabbit. An ancient legend says a beautiful Chinese girl called Chango-o has been living there for 4,000 years. It seems she was banished to the moon because she stole the pill of immortality from her husband. You might also look for her companion, a large Chinese rabbit, who is easy to spot since he is always standing on his hind feet in the shade of a cinnamon tree. The name of the rabbit is not reported.

Michael Collins: OK. We’ll keep a close eye out for the bunny girl.” 

Myth 6: Humans didn’t actually land on the moon

Noble said the most common myth she is asked about is the idea that the Apollo missions never landed on the moon. Naysayers claim that the necessary technology did not exist to make such a trip possible in the late 1960s and early 1970s.

Noble said she normally responds to these claims by pointing to her research looking at the rocks and soils returned by the Apollo astronauts, and how they differ from terrestrial rocks.

But modern lunar missions have helped to provide further evidence for the historic missions.

“Another great response is the images from LRO that actually show the footprints and flags we left behind,” Noble said.

Editor’s note: If you snap an amazing photo of Sunday’s supermoon lunar eclipse and want to share it with Space.com, send images and comments in to managing editor Tariq Malik at spacephotos@space.com.

Follow Nola Taylor Redd on Twitter @NolaTRedd or Google+. Follow us @Spacedotcom, Facebook or Google+. Originally published on Space.com.

This image of Mars was captured by India’s Mangalyaan orbiter, which arrived at the Red Planet in September 2014. Credit: Indian Space Research Organisation

India’s first-ever Mars probe is now one year into its historic mission, and it’s still going strong.

The Mars Orbiter Mission (MOM) spacecraft, also known as Mangalyaan, arrived at the Red Planet on the night of Sept. 23, 2014 (Sept. 24 GMT and Indian Standard Time), just two days after NASA’s Mars Atmosphere and Volatile Evolution probe (MAVEN) reached Mars orbit.

Mangalyaan, which means “Mars craft” in Sanskrit, was the first interplanetary probe ever launched by India, and its $73 million mission is primarily a technology demonstration, officials with the Indian Space Research Organisation (ISRO) have said. [See the amazing Mars photos by India’s Mangalyaan probe]

But Mangalyaan carries a color camera and four scientific instruments, which it has been using to study the Martian surface and atmosphere over the past 12 months.

To celebrate the anniversary, ISRO has compiled some of MOM’s best images and most interesting scientific results in a 120-page “Mars Atlas,” which you can download free of charge here:
http://www.isro.gov.in/pslv-c25-mars-orbiter-mission/celebrating-one-year-of-mars-orbiter-mission-orbit-release-of-mars

MOM’s mission was originally scheduled to last 6 months, but operations were extended by an additional 6 months earlier this year. Further extensions are likely; ISRO officials have said that Mangalyaan has enough fuel onboard to keep studying Mars for years to come.

MOM might even last long enough to welcome a sister craft to Mars orbit. ISRO officials announced last year that the country plans to launch a Mangalyaan 2 mission in the 2018-2020 time frame.

MOM and MAVEN, which seeks to determine how fast Mars’ atmosphere is being lost to space, are not the only operational spacecraft orbiting the Red Planet. NASA’s Mars Odyssey and Mars Reconnaissance Orbiter are also eyeing the planet from above, as is the European Space Agency’s Mars Express probe. (These latter three spacecraft arrived at Mars in 2001, 2006 and 2003, respectively.)

Two NASA rovers are also actively exploring the Martian surface — Opportunity, which landed in January 2004, and Curiosity, which survived a dramatic and unprecedented “sky crane” touchdown in August 2012.

Follow Mike Wall on Twitter @michaeldwall and Google+. Follow us @Spacedotcom, Facebook or Google+. Originally published on Space.com.

NASA’s MAVEN spacecraft, shown here in an artist’s illustration, celebrated one year in Mars orbit on Sept. 21, 2015. Credit: NASA/Goddard

NASA’s newest Mars probe has now been circling the Red Planet for a year.

The Mars Atmosphere and Volatile EvolutioN (MAVEN) spacecraft arrived in orbit around the Red Planet on Sept. 21, 2014, 10 months after blasting off from Florida’s Cape Canaveral Air Force Station.

MAVEN endured a two-month checkout phase on orbit and then began studying Mars’ atmosphere, in an attempt to determine how fast the planet’s air is escaping into space. Such information will help researchers better understand how and when Mars shifted from a relatively warm and wet world in the ancient past to the cold and dry planet it is today, NASA officials have said. [NASA’s MAVEN Mission to Mars: 10 Surprising Facts]

Everything is going well so far with the $671 million mission, and all of MAVEN’s systems and instruments are in good shape, team members said.

“We’re obtaining an incredibly rich data set that is on track to answer the questions we originally posed for MAVEN and that will serve the planetary science community for a long time to come,” MAVEN principal investigator Bruce Jakosky, of the University of Colorado’s Laboratory for Atmospheric and Space Physics in Boulder, said in a statement.

MAVEN’s first year at Mars has been quite eventful. In October 2014, for example, the spacecraft survived the close approach of Comet Siding Spring, which zoomed within just 87,000 miles (139,500 kilometers) of the Red Planet’s surface.

Observations by MAVEN, NASA’s Mars Reconnaissance Orbiter (MRO) and Europe’s Mars Express spacecraft revealed that dust and other material shed by the comet created a temporary layer high up in the Red Planet’s atmosphere.

MAVEN has also spotted auroral displays — similar to the northern and southern lights here on Earth — that penetrate surprisingly deeply into the Martian atmosphere and discovered a strange dust cloud that extends from about 93 miles (150 km) above the planet’s surface to an altitude of 190 miles (300 km).

The spacecraft can also serve a relay function, helping link up communications between NASA’s Opportunity and Curiosity rovers and their handlers on Earth.

MAVEN’s primary, one-year mission will end this November, but NASA has extended the probe’s operations through at least September 2016.

MAVEN, MRO and Mars Express are three of five operational spacecraft currently studying the Red Planet from orbit. The others are NASA’s Mars Odyssey probe and India’s first-ever Red Planet spacecraft, which is known as Mangalyaan. Mangalyaan marks its one-year Mars anniversary tomorrow (Sept. 24).

Follow Mike Wall on Twitter @michaeldwall and Google+. Follow us @Spacedotcom, Facebook or Google+. Originally published on Space.com.

Luc Jamet (France) captured the total solar eclipse of March 20, 2015, from Svalbard, Norway — one of only two habitable locations able to witness totality — just 16 seconds after it began. Credit: © Luc Jamet

The winning images from the Royal Observatory Greenwich’s Insight Astronomy Photographer of the Year competition were announced last week, and the list is an awe-inspiring collection of celestial awesomeness.

A record number of astrophotographers (more than 2,700) from 59 countries competed in the annual astronomy photography contest, according to the official website. The competition welcomes all kinds of astrophotography, from skyscapes to deep-space photos.

The contest’s overall winner, titled “Eclipse Totality Over Sassendalen,” captures the 2015 solar eclipse, taken on an icy plane in the Norwegian archipelago of Svalbard. Taken by Luc Jamet of France, the image captures the black moon blocking out the sun, but the light of the sun’s corona can still be seen surrounding it. [See the Winning Photos: Astronomy Photographer of the Year 2015]

When describing this year’s winning solar eclipse image, contest judge Melanie Vandenbrouck said, “It is one of those heart-stoppingly beautiful shots for which you feel grateful to the photographer for sharing such an exceptional moment. The delicate disc of the occulted sun is perfectly silhouetted in the sky, and you can almost feel the below-zero temperature, the cool breeze of the Arctic. The snow is pristine, as if no one had ever stepped on it. This is an otherworldly landscape, which could be on an as-yet-unexplored planet.”

“Sunderland Noctilucent Cloud Display,” the runner up in the skyscapes category in the Royal Observatory’s annual Insight Astronomy Photographer of the Year competition. Taken July 7, 2014 at Seaburn Beach, Sunderland, UK.
Credit: Matt Robinson

The contest is run by the Royal Observatory Greenwich, in association with Insight Investment and BBC Sky at Night Magazine. Photo submissions to the competition are divided into nine categories: skyscapes; aurorae; galaxies; our moon; our sun; people and space; planets, comets and asteroids; stars and nebulas; and the young astronomy photographer of the year. There are also two special categories: The Sir Patrick Moore prize for best newcomer, and the robotic scope prize.

Judging this year’s competition was likely no easy task. The runner-up in the skyscape category, titled “Sunderland Noctilucent Cloud Display,” by Matt Robinson of the United Kingdom, is absolutely breathtaking. It captures a strange and beautiful evening sky that contains the striped colors of a rainbow; stretching out above a body of water, the light reflects off the clouds, making the sky appear to ripple like water. The second runner up, titled “River of Light,” is an awesomely detailed shot of the Milky Way. The photo captures an incredible amount of color and texture in our home galaxy as it stretches across the night sky.

“River of Light,” a highly commended entry in the skyscapes category in the Royal Observatory’s annual Insight Astronomy Photographer of the Year competition. Taken July 21, 2014 at Lac d’Aumar Parc National des Pyrénées, Hautes-Pyrénées, France.
Credit: Martin Campbell

The winner of the planets, comets and asteroids category captured an incredible coincidental alignment of a comet and a nebula. Titled “The Arrow Missed the Heart,” by Lefteris Velissaratos of Greece, it appears to show a glowing comet, with a long, narrow tail, piercing the heart of a deep-red nebula. Of course, it’s only a trick of perspective (the nebula is much farther away than the comet), but the resulting image is still breathtaking.

The winning images, along with the runners-up and many highly commended images from the competition, are being shown in a free exhibition at the Royal Observatory’s Astronomy Centre in Greenwich, England. Winners and short-listed entries also will be published in the competition’s official book, which will be available beginning Nov. 5.

Follow Calla Cofield @callacofield.Follow us @Spacedotcom, Facebook and Google+. Original article on Space.com.

Sebastian Voltmer (Germany) snapped a close encounter between our neighbor Mars and Comet C/2013 A1, AKA Siding Spring, as it passed through the night…Read More » sky on Oct. 22, 2014. To obtained Voltmer used the SBIG STL11000M camera at Siding Spring Observatory, Coonabarabran, New South Wales, Australia.   Less «

The rare “supermoon” total lunar eclipse on Sunday (Sept. 27) will mark the end of a great eclipse-viewing era.

The Sunday evening eclipse is the last in a “tetrad” — a term for four total lunar eclipses happening at six-month intervals — that has been stunning skywatchers across the United States for the past 18 months, and also sparking conspiracy theories about what it could mean.

“The most unique thing about the 2014-2015 tetrad is that all of them are visible for all or parts of the USA,” NASA eclipse expert Fred Espenak said in a statement last year. [Supermoon Lunar Eclipse: Complete Blood Moon Coverage]

What makes Sunday’s eclipse even more special, however, is that it will occur when the moon is at its closest point to Earth in its elliptical orbit and therefore appears abnormally large and bright in the sky. This so-called “supermoon” eclipse will be the first one since 1982, and the last until 2033.

A lunar eclipse happens when the moon passes into the shadow of the Earth. When the moon is totally eclipsed, it goes completely in the shadow, turns red or reddish-brown, and stays that way for up to an hour. No special equipment or eye protection is needed to see it, and it is viewable anywhere the sky is dark and the moon is visible.

There are several kinds of lunar eclipses, such as when the moon passes into the edge of the palest part of the shadow (a penumbral eclipse) or when the moon partially enters a deeper part of the shadow (a partial eclipse).  

While the alignment of the sun, Earth and moon make lunar eclipses happen about twice a year, usually it’s a total eclipse followed by a different kind of eclipse. Tetrads have been a frequent occurrence in the 21st century — there are eight in this century alone, Espenak pointed out in the statement — but that doesn’t always happen. Between 1600 and 1900, there were no tetrads at all.

But the number of “blood moons” seen in the past 18 months sparked some conspiracy theories about possible dangers to humanity. In 2014, according to Space.com skywatching columnist Joe Rao, online rumors drew a link between the eclipses and biblical prophecies of the apocalypse — a theory also popularized in a book called “Four Blood Moons” by John Hagee (Worthy Publishing, 2013).

Editor’s Note: If you snap an amazing picture of the Sept. 27 total lunar eclipse, you can send photos, comments and your name and location to managing editor Tariq Malik at spacephotos@space.com.

Follow Elizabeth Howell @howellspace, or Space.com @Spacedotcom. We’re also on Facebook and Google+. Original article on Space.com.

Cislunar Explorer, a 3U cubesat a team at Cornell University is developing for a NASA-funded Lunar Derby. Credit: Cislunar Explorer

WASHINGTON — Five teams, ranging from university students to a group of engineers dispersed across the country, received $20,000 each from NASA in the first milestone of a competition to develop deep space cubesat technologies.

The teams, announced by NASA at a Sept. 9 briefing, had the highest scores in the first of four “ground tournaments” that make up the initial phase of the agency’s $5 million Cube Quest Challenge. That tournament, held in early August, featured 13 teams who presented their initial spacecraft designs.

“Cube Quest is an opportunity for non-government cubesat developers and builders to compete in lunar orbit and deep space for accomplishments in communications, navigation and longevity,” said Jim Cockrell of NASA’s Ames Research Center. Cockrell is manager of the competition, part of the agency’s Centennial Challenges prize program. [Tiny Satellites Launched from Space Station (Photos)]

The ground tournaments are optional elements of the overall competition, intended to guide teams through the development of their spacecraft as they mature from initial concepts to flight hardware. Participating teams are scored on how well they meet the requirements of each tournament, and the three with the highest cumulative scores will win flights of their spacecraft as secondary payloads on the first Space Launch System mission, Exploration Mission 1 (EM-1), in 2018.

The first ground tournament did not involve any hardware, and Cockrell likened it to a mission concept review that takes place early in the development of a typical NASA mission. Judges assessed the capabilities of each proposed mission and compliance with mission rules and SLS safety requirements.

“It was the first opportunity for teams to present their concepts for how they intend to win the Cube Quest Challenge,” he said. “Ground Tournament 1 demonstrates that teams are on a good trajectory for launch on EM-1.”

Some of the winning teams are linked to universities that have experience with cubesats. A space systems design class at the Massachusetts Institute of Technology started work on the KitCube spacecraft this spring, said Kerri Cahoy, a professor of aeronautics and astronautics there. KitCube is designed to go into lunar orbit and demonstrate a laser communications system.

Another team, Cislunar Explorers, is composed mostly of students at Cornell University. “The work represents the culmination of lots of Ph.D.-level research and some undergraduate research from the last five or six years at the university,” said Mason Peck, a Cornell engineering professor who served as NASA chief technologist from 2011 to 2013.

Peck said their spacecraft will demonstrate several key technologies, including a propulsion system that uses solar power to convert water into hydrogen and oxygen propellants. “It’s a pathfinder for the sustainable exploration and settlement of the solar system,” he said.

Other winning teams have less traditional backgrounds. “There’s 12 of us across the United States” working on Team Miles, said team leader Wes Faler. Many of them are located in Tampa, Florida, including Faler, but others are based in California, New York and South Carolina.

Faler said the team takes its name from a line in a Robert Frost poem: “And miles to go before I sleep.” After going into orbit around the Moon, he said, the spacecraft will perform an extended mission, traveling towards Mars to test autonomous navigation technology.

Ragnarok Industries of Wilmington, Delaware, was established by a group of former engineering interns at NASA’s Goddard Space Flight Center. Their satellite, Heimdallr, is intended to test advanced propulsion and communications technologies for missions beyond Earth orbit, said company co-founder Luigi Balarinni.

Novel Engineering of Cocoa Beach, Florida, is working with several other local companies, including Craig Technologies and Harris Corp., the latter providing a deployable mesh antenna for its cubesat, named Space Pig. The name, team members said, came from elementary school students during an outreach event.

The ultimate goal of the competition is to fly cubesats into lunar orbit or deep space. A total of $3 million is offered in prizes for the “Lunar Derby” part of the competition, for both being able to enter lunar orbit and to demonstrate communications capabilities and longevity. An additional $1.5 million is for a “Deep Space Derby” to achieve communications and longevity goals.

NASA’s Cockrell said the next ground tournament is scheduled for early 2016. Teams can participate in that round, which he compared to a preliminary design review, regardless of their performance, or even participation, in the August tournament.

Teams that do not participate in the ground tournaments, or who do not finish in the top three in total points, can still pursue the deep space and lunar prizes by arranging their own launches. The competition ends, and any prizes awarded, one year after the EM-1 launch.

This story was provided by SpaceNews, dedicated to covering all aspects of the space industry.

This image shows the gas density distribution of one instance in time of the model starburst galaxy, spanning approximately 650,000 light-years across. Extreme star formation in the central galaxy is fueled by significant gas inflows, rendering it extremely bright. Credit: Desika Narayanan

The mystery of how the brightest galaxies in the universe form may soon be solved, as research now suggests they may be powered by prodigious flows of gas.

The most luminous galaxies in the universe, known as submillimeter galaxies, were first discovered more than a decade ago. Most of the vast amounts of light they emit gets absorbed by interstellar dust and re-emitted at far-infrared submillimeter wavelengths outside the visible range. As a result, they remained undiscovered until astronomers began combing the skies at these wavelengths.

“They have luminosities maybe hundreds to thousands of times that of the Milky Way,” study lead author Desika Narayanan, an astrophysicist at Haverford College in Pennsylvania, told Space.com. [Great Images of Galaxies Across the Universe]

This image shows distribution of galaxies across the infrared luminous region, at a given instance in time; colors denote gas density. The model suggests that extreme infrared-luminous regions observed by submillimeter-wave telescopes are often comprised of groups of galaxies in the early universe (just a few billion years after the Big Bang) that will grow to be massive clusters of galaxies at the present day.
Credit: Robert Thompson (NCSA)

Submillimeter galaxies existed about 3 billion years ago during an epoch known as cosmic noon, when galaxies formed stars at extraordinary rates. Submillimeter galaxies birthed stars at the greatest rates known — 1,000 times greater than that of the Milky Way today. No such galaxies are currently seen in the cosmos, researchers said.

The extreme properties of these extraordinary galaxies have challenged existing models of galaxy formation, sparking vigorous debate among astronomers. Although computer simulations have been able to form sufficiently bright galaxies, the models could not match other features of these behemoths, such as their mass and star-formation rates.

There are two schools of thought as to how these galaxies may have formed. One suggests that collisions between pairs of gas-rich galaxies drove spectacular and relatively brief 100-million-year-long bursts of star formation. The other suggests these galaxies slowly accreted mass over the course of about 1 billion years. However, neither scenario could fully explain the known features of these galaxies.

Now researchers have presented new galaxy-formation simulations that for the first time are good matches for all the known properties of submillimeter galaxies, findings that were detailed online today (Sept. 23) in the journal Nature.

“Everyone had assumed these galaxies are the result of big galaxy mergers, because the brightest galaxies in the nearby universe are all the results of galaxy mergers,” Narayanan said. “But our simulations suggest the formation mechanism of these galaxies was a slow and steady buildup of gas, where gas accretes from intergalactic space and piles up in these galaxies.”

These new simulations achieved levels of realism that previous models lacked by using a “zoom” technique, said astrophysicist Romeel Davé at the University of the Western Cape in Cape Town, South Africa, who did not take part in this research. In this technique, the researchers both simulated galaxies and modeled patches of these galaxies at much higher resolutions.

This approach gave the researchers accurate looks at how these galaxies arose bit by bit, while also providing the big picture of how each galaxy interacted with its surroundings, Davé wrote in a commentary on this work in the same issue of Nature.

The new simulations suggest these galaxies sustained star-formation rates of about 500 to 1,000 suns per year for 1 billion years or so. This intense activity was a natural, long-lasting phase in the evolution of these massive galaxies.

Although supernova explosions from dying stars can propel gas outward from these galaxies and thus drive away the fuel needed for star formation, the scientists found these outflows had trouble escaping the intense gravitational pulls of these galaxies. Instead, the new simulations suggest, gas often rained back down on these galaxies and got recycled into new stars.

In the future, the researchers want to investigate other kinds of galaxies seen during cosmic noon, they said.

“Some have extremely massive black holes a billion times the mass of the sun, and some are very compact and relatively dead, not forming stars rapidly,” Narayanan said. “It’s interesting to see that the populations of these galaxies are similar to the submillimeter galaxy population, and it’s tempting to say there’s some connection between the three in some evolutionary sense.

“We want to see if there is a connection between these kinds of galaxies — does one turn into another?” Narayanan added. “If so, what physical processes drive that transformation? And in the grand scheme, how does that activity relate to what their descendants look like today, and how do we find these great-great-great-grandchildren in the local universe?”

Follow us @Spacedotcom, Facebook or Google+. Originally published on Space.com.

This Sunday night moon observers have the chance to see a lunar triple treat, weather permitting.

First, the moon will be full, as it always must be for a lunar eclipse to occur. This is a special full moon, because this is the Harvest Moon. Because the angle of the ecliptic —the path the moon and planets follow across the sky —is low to the horizon, the moon rises about the same time every night, giving farmers an extra supply of light when they most need it, at harvest time.

Second, the full moon will be at its closest to Earth in all of 2015, what is known to astronomers as a “perigee moon.” In recent years this has become known as a “supermoon.” Perigee (meaning “closest to Earth”) occurs at 10 p.m. EDT, the moon being a mere 222,374 miles (357,877 km) from Earth. [Supermoon Lunar Eclipse: When and Where to See It]

In fact, the human eye can’t detect the 5-percent difference in size between the moon at perigee and the moon at apogee (farthest from Earth), but everyone who looks at the moon Sunday night (Sept. 27) will swear it looks bigger than usual. Partly that is because, when seen low on the horizon, the human eye and brain combine to create an optical illusion known as the moon illusion, whereby the moon (and other objects) viewed close to the horizon seem larger than when seen overhead. Cover the moon with a dime at arm’s length, and you’ll see that there is no difference.

Sunday’s lunar eclipse, seen as the moon enters the shadow’s umbra at 9:07 p.m. EDT.
Credit: Starry Night Software

The only noticeable effect of a perigee moon is that the ocean tides will be a bit higher than usual for the day of the full moon and the next three days.

The third, and most important part of this treat, is that we will have a total eclipse of the moon. At most full moons, the sun, Earth and moon line up approximately, but because of the tilt of the moon’s orbit, the moon passes above or below the Earth’s shadow, and avoids being eclipsed.

At certain points in the moon’s orbit, sun, Earth and moon line up exactly, and the Earth’s shadow falls across the face of the moon, and we have a lunar eclipse. This is what will happen Sunday night. [Supermoon Lunar Eclipse: Viewing Maps]

The moon’s shadow has two parts: a darker inner part called the umbra, and a lighter outer part called the penumbra. This is because the sun is not a point source of light, so its light leaks around the edge of the Earth, and results in an unsharp shadow. In passing through the Earth’s atmosphere, the light turns red or orange, so that the light that actually reaches the moon is tinted by thousands of sunsets and sunrises all around the periphery of the Earth.

One result of these multiple sunrises and sunsets is that the moon during an eclipse is often tinted red, which is the origin of the idea of a lunar eclipse being a “Blood Moon.” It isn’t a far stretch of the human imagination to turn this Blood Moon into a portent of disaster.

A lot has been made in the media of this eclipse being the final event in a foursome of total eclipses known as a “lunar tetrad.” There is nothing unusual about four lunar eclipses in two years, since we usually average at least two lunar eclipses every year, though not all are total.

In fact, there was no tetrad of total eclipses at all, because the last lunar eclipse, on April 4, was not really a total eclipse. According to the usual way of calculating eclipses, the moon spent only 4.5 minutes in the umbral shadow, but recently this calculation method has been corrected, resulting in the April eclipse failing to be total at all.

This Sunday’s lunar eclipse is a true total eclipse, with the moon being in the umbra for a full 1 hour and 22 minutes.

Observers in eastern and central regions of North America will get to see the whole eclipse; those farther west will see the moon rise already partially eclipsed. Observers in Europe and Africa will see the eclipse before dawn on Monday (Sept. 28).

This brings up the question of dates and times, which often causes confusion. Even a usually reliable source like Canada’s Weather Network got the date of this eclipse wrong.

Officially, mid-eclipse occurs Sept. 28 at 02:47 Universal Time, which is the same as Greenwich Mean Time (but not British Summer Time). Subtracting 4 hours, this places mid-eclipse in the Eastern Daylight Time zone at 10:47 p.m. on Sept. 27; the date changes at midnight. So be sure you look for the eclipse on Sunday evening. If you wait until Monday evening, you will be a day late.

Here are the important times in Eastern Daylight Time; if you’re using CDT, MDT, or PDT, the times will be earlier by 1, 2 or 3 hours.

All times in EDT

• 8:11:46 p.m. — Moon enters penumbra
• 9:07:12 p.m. — Moon enters outer edge of umbra
• 10:11:11 p.m. — Moon completely in umbra
• 10:47:09 p.m. — Mid-eclipse
• 11:23:07 p.m. — Moon begins to emerge from umbra
• 12:27:06 a.m. — Moon completely out of umbra
• 1:22:33 a.m. — Moon leaves penumbra

As always, we look forward to your pictures of this beautiful event.

Editor’s note: If you snap an amazing picture of the Sept. 27 supermoon lunar eclipse and would like to share for a possible story or image gallery, send photos, comments and your name and location to managing editor Tariq Malik at spacephotos@space.com.

This article was provided to SPACE.com by Simulation Curriculum, the leader in space science curriculum solutions and the makers of Starry Night and SkySafari. Follow Starry Night on Twitter @StarryNightEdu. Follow us @Spacedotcom, Facebook and Google+. Original article on Space.com.

Extremely luminous early galaxies – such as those simulated here in infrared light – established the structure of galactic clusters observed today by sub-millimeter wavelength telescopes. Visualization by Robert Thompson (NCSA) Music by Thomas Bergersen

Credit: Visualization: Robert Thompson (NCSA) / Music: Thomas Bergersen