Virtual Star Party for Sep. 9, 2012 – Neptune and Uranus Edition

After a brief hiatus, we’re back with our Virtual Star Parties, broadcasting our view of the night sky into a live Google+ Hangout. Last night was a special occasion, as astronomer Mike Phillips broadcast our first view of the planet Neptune. And then, just to show off, he found Uranus too. It was amazing to see those objects in our hangout for the first time. We’re now just waiting for Mercury to complete the whole set. Who will be the first to show us Mercury?

Astronomers: Cory Schmitz, Mike Phillips, John Kramer

Commentators: Gary Gonella, Pamela Gay, Scott Lewis, Emily Lakdawalla

Want to watch a Virtual Star Party in person? I’ve already posted the Event for next week on Google+. You can join the event there and add it to your calendar, so you’ll get a notification of when we’re about to go live.

An Awesome View of Curiosity’s Tummy

Curiosity’s underside as imaged by the MAHLI camera. Credit: NASA/JPL/MSSS; image editing by Astro0.

One of Curiosity’s amazing color cameras, the Mars Hand Lens Imager (MAHLI) that is mounted on the turret at the end of the MSL robotic arm, is now officially in action, with its dust cover removed over the weekend. The first picture it sent back to Earth was of the soil in its field of view (see below). That’s great, as the camera’s purpose is to acquire close-up images of materials on the Martian surface—rocks, fine particles and even frost. But then engineers commanded the camera to take a look at Curiosity’s underbelly – the rover’s ‘tummy’ so to speak. And the views are awesome, especially when some of the image wizards at UnmannedSpaceflight stitched a few of the images together to put together a mosaic of the entire view of the rover’s underside. This image was put together by Astro0 at UMSF. Click the image to see a larger version on his website.

The first image to come from Curiosity’s Mars Hand Lens Imager (MAHLI) with the dust cap off. Credit: NASA/MSL-Caltech

MAHLI, built by Malin Space Science Systems (MSSS) will be used to help characterize the geology of the site investigated by MSL, and it will be used to document the materials being examined by MSL’s geochemical and mineralogical experiments.

You can see the “raw images” at the MSL website, the images that are just being beamed back from the rover, and see more at UnmannedSpaceflight; Emily Lakdawalla at the Planetary Blog also has some images she has put together from MAHLI’s views of Curiosity’s underside.

Here’s a picture of the camera itself:

The Mars Hand Lens Imager (MAHLI) camera head. The knife is 88.9 mm (3.5 inches) long. Image credit: Malin Space Science Systems

MAHLI is the equivalent of a 2 Megapixel camera. Because MAHLI can focus at infinity, in addition to being able to get microscopic views of surface materials MAHLI can also be used for other purposes, including inspection of areas on the rover or imaging the local landscape — as the images here attest.

MAHLI can also acquire multiple images of the same feature at different focus positions; additionally look upcoming for 3-D views of selected targets from this camera, since it is located on the robotic arm, it will be relatively easy to move the camera to take two images of the same object from different positions.

Learn more about MAHLI at the Malin Space Science Systems website.

Clay Deposits Don’t Prove Existence of Ancient Martian Lakes

HiRISE image of branching features in the floor of Antoniadi Crater thought to contain clay material. (NASA/JPL/University of Arizona)

In the hunt for evidence of a warmer, wetter past on Mars, clay deposits have been viewed as good indications that stable liquid water existed on its surface for some time — perhaps even long enough to allow life to develop. But new research conducted here on Earth shows that some clays don’t necessarily need lakes of liquid water to form. Instead they can be the result of volcanic activity, which is not nearly so hospitable to life.

A research team led by Alain Meunier of the Université de Poitiers in France studied lavas containing iron and magnesium — similar to ancient clays identified on the surface of Mars — in the French Polynesian atoll of Moruroa. The team’s findings show that the same types of clay outcrops can be caused by the solidifying of water-rich magma in a volcanic environment, and don’t require Earthlike aquatic conditions at all.

The results also correlate to the deuterium-to-hydrogen (D/H) ratio within clays found in Martian meteorites.

Read: Life from Mars Could Have Polluted Earth

“To crystallize, clays need water but not necessarily liquid water,” said Alain Meunier to the Agençe France-Presse (AFP). “Consequently, they cannot be used to prove that the planet was habitable or not during its early history.”

Additionally, the clay deposits found on Mars can be several hundred meters thick, which seems to be more indicative of upwelling magma than interactions with water.

“[This] new hypothesis proposes that the minerals instead formed during brief periods of magmatic degassing, diminishing the prospects for signs of life in these settings,” wrote Brian Hynek from the Department of Geological Sciences at the University of Colorado, in response to the paper by Meunier et al. which was published in the September 9 edition of the journal Nature Geoscience.

This does not necessarily mean that all Martian clays weren’t formed in the presence of water, however. Gale Crater — where NASA’s Curiosity rover is now exploring — could very well have been the site of a Martian lake, billions of years in the past. Clays found there could have been created by water.

Read: Take a Trip to Explore Gale Crater

According to Bethany Ehlmann of the California Institute of Technology, co-author of the study, “there are particular characteristics of texture” to clays formed under different conditions, and “Gale is a different flavor of Mars.”

Perhaps Curiosity will yet discover if Gale’s original flavor was more cool and wet than hot and spicy.

Read more on New Scientist and Cosmos Magazine.

Inset image: Moruroa Atoll (NASA) 

Weekly SkyWatcher’s Forecast: September 10-16, 2012

Greetings, fellow SkyWatchers! With very little Moon to contend with this week, it will be a great time to take on some challenging studies like the Helix Nebula, Saturn Nebula, Stephen’s Quintet and more. It’s time to get out your big telescope and head for some dark skies… Because this week isn’t for the beginner! Whenever you’re ready, I’ll see you out back…

Monday, September 10 – Today is the birthday of James E. Keeler. Born in 1857, the American Keeler was a pioneer in the field of spectroscopy and astrophysics. In 1895, Keeler proved that different areas in Saturn’s rings rotate at different velocities. This clearly showed that Saturn’s rings were not solid, but were instead a collection of smaller particles in independent orbits.

Now, let’s head on to Capricornus and drop about four finger-widths south of its northeastern most star – Delta – and have a look at M30 (Right Ascension: 21 : 40.4 – Declination: -23 : 11). Discovered in 1764 by Charles Messier, binocular observers will spot this small, but attractive, globular cluster easily in the same field with star 41. For telescopic observers, you will find a dense core region and many chains of resolvable stars in this 40,000 light year distant object. Power up!

Let’s get some more practice in Capricornus, and take on a more challenging target with confidence. Locate the centermost bright star in the northern half of the constellation – Theta – because we’re headed for the “Saturn Nebula”.

Three finger-widths north of Theta you will see dimmer Nu, and only one finger-width west is NGC 7009 (Right Ascension: 21 : 04.2 – Declination: -11 : 22). Nicknamed the “Saturn Nebula”, this wonderful blue planetary is around 8th magnitude and achievable in small scopes and large binoculars. Even at moderate magnification, you will see the elliptical shape which gave rise to its moniker. With larger scopes, those “ring like” projections become even clearer, making this challenging object well worth the hunt. You can do it!

Tuesday, September 11 –Today celebrates the birthday of Sir James Jeans. Born in 1877, English-born Jeans was an astronomical theoretician. During the beginning of the 20th century, Jeans worked out the fundamentals of the process of gravitational collapse. This was an important contribution to the understanding of the formation of solar systems, stars, and galaxies.

So, are we ready to try for the “Helix”?

Located in a sparsely populated area of the sky, this intriguing target is about a fist width due northwest of bright Formalhaut and about a fingerwidth west of Upsilon Aquarii. While the NGC 7293 (Right Ascension: 22 : 29.6 – Declination: -20 : 48) is also a planetary nebula, its entirely different than most… It’s a very large and more faded edition of the M57! On a clear, dark night it can be spotted with binoculars since it spans almost one quarter a degree of sky. Using a telescope, stay at lowest power and widest field, because it is so large. It you have an OIII filter, this faded “ring” becomes a braided treat!

Wednesday, September 12 – Today in 1959, the USSR’s Luna 2 scored a mark as it became the first manmade object to hit the moon. The successful mission landed in the Paulus Putredinus area. Today also celebrates the 1966 Gemini 11 launch.

Tonight let’s take the time to hunt down an often overlooked globular cluster – M56. Located roughly midway between Beta Cygni and Gamma Lyrae (RA 19 15 35.50 Dec +30 11 04.2), this class X globular was discovered by Charles Messier in 1779 on the same night he discovered a comet, and was later resolved by Herschel. At magnitude 8 and small in size, it’s a tough call for a beginner with binoculars, but is a very fine telescopic object. With a general distance of 33,000 light-years, this globular resolves well with larger scopes, but doesn’t show as much more than a faint, round area with small aperture. However, the beauty of the chains of stars in the field makes it quite worth the visit!

While you’re there, look carefully: M56 is one of the very few objects for which the photometry of its variable stars was studied strictly with amateur telescopes. While one bright variable star had been known previously to exist, up to a dozen more have recently been discovered. Of those, six had their variability periods determined using CCD photography and telescopes just like yours!

Thursday, September 13 – Today in 1922, the highest air temperature ever recorded at the surface of the Earth occurred. The measurement was taken in Libya and burned in at a blistering 136F (58C), but did you know that the temperatures in the sunlight on the Moon double that? If you thought the surface of the Moon was a bit too warm for comfort, then know surface temperatures on the closest planet to the Sun can reach up to 800F (427C) at the equator during the day! As odd as it may sound, even that close to the Sun – Mercury could very well have ice deposits hidden below the surface at its poles.

Tonight we’ll move on to Aquila and look at the hot central star of an interesting planetary nebula – NGC 6804 (Right Ascension: 19 : 31.6 – Declination: +09 : 13). You’ll find it almost 4 degrees due west of Altair. Discovered by Herschel and classed as open cluster H VI.38, it wasn’t until Pease took a closer look that its planetary nature was discovered. Interacting with clouds of interstellar dust and gases, NGC 6804 is a planetary in decline, with its outer shell around magnitude 12 and the central star at about magnitude 13. While only larger telescopes will get a glimpse of the central, it’s one of the hottest objects in space – with temperatures around 30,000K!

If that’s not “hot” enough for you, then take a look straight overhead at brilliant star Vega. It is a “Sirian type” star and with a surface temperature of about 9200 degrees Kelvin, it’s twice as hot as our own Sun. At around 27 light years away, our entire solar system is moving towards Vega at a speed of 12 miles per second, but don’t worry… It will take us another 450,000 years to get there. If we were to arrive tonight, we’d find that Vega is around 3 times larger than Sol and that it also has a 10th magnitude companion that can often be resolved in mid-sized scopes. It’s one of the first stars to ever be photographed. Back in 1850, that simple star – Vega – took and exposure time of 100 seconds through a 15? scope. How times have changed!

Friday, September 14 – Tonight’s destination is not an easy one, but if you have a 6? or larger scope, you’ll fall in love a first sight! Let’s head for Eta Pegasi and slightly more than 4 degrees north/northeast for NGC 7331 (Right Ascension: 22 : 37.1 – Declination: +34 : 25).

This beautiful, 10th magnitude, tilted spiral galaxy is very much how our own Milky Way would appear if we could travel 50 million light years away and look back. Very similar in both structure to ourselves and the “Great Andromeda”, this particular galaxy gains more and more interest as scope size increases – yet it can be spotted with larger binoculars. At around 8? in aperture, a bright core appears and the beginnings of wispy arms. In the 10? to 12? range, spiral patterns begin to emerge and with good seeing conditions, you can see “patchiness” in structure as nebulous areas are revealed and the western half is deeply outlined with a dark dustlane. But hang on… Because the best is yet to come!

Saturday, September 15 – In 1991 the Upper Atmosphere Research Satellite (UARS) was launched from Space Shuttle Discovery. The successful mission lasted well beyond its life expectancy – sending back critical information about our ever-changing environment. After 14 years and 78,000 orbits, UARS remains a scientific triumph.

If you’re up early, why not check out Mars? While the red planet is visible, it’s also rather small at the moment, with an apparent diameter of less than .5”. Can you still spot some surface details?

Tonight return to the NGC 7331 with all the aperture you have. What we are about to look at is truly a challenge and requires dark skies, optimal position and excellent conditions. Now breathe the scope about one half a degree south/southwest and behold one of the most famous galaxy clusters in the night.
In 1877, French astronomer – Edouard Stephan was using the first telescope designed with a reflection coated mirror when he discovered something a bit more with the NGC 7331. He found a group of nearby galaxies! This faint gathering of five is better known as “Stephan’s Quintet” and its members are no further apart than our own Milky Way galaxy.

Visually in a large scope, these members are all rather faint, but their proximity is what makes them such a curiosity. The Quintet is made up of five galaxies numbered NGC 7317, 7318, 7318A, 7318B, 7319 and the largest is 7320 (Right Ascension: 22 : 36.1 – Declination: +33 : 57). Even with a 12.5? telescope, this author has never seen them as much more than tiny, barely there objects that look like ghosts of rice grains on a dinner plate. So why bother?

What our backyard equipment can never reveal is what else exists within this area – more than 100 star clusters and several dwarf galaxies. Some 100 million years ago, the galaxies collided and left long streamers of their materials which created star forming regions of their own, and this tidal pull keeps them connected. The stars within the galaxies themselves are nearly a billion years old, but between them lay much younger ones. Although we cannot see them, you can make out the soft sheen of the galactic nucleii of our interacting group.

Enjoy their faint mystery!

Sunday, September 16 – It’s New Moon! For those of you who have waited on the weekend to enjoy dark skies, then let’s add another awesome galaxy to the collection. Tonight set your sights towards Alpha Pegasi and drop due south less than 5 degrees to pick up NGC 7479 (Right Ascension: 23 : 04.9 – Declination: +12 : 19).

Discovered by William Herschel in 1784. this tantalizing 11 magnitude barred spiral galaxy has had a supernova in its nucleus as recently as 1990. While the 16th magnitude event is no longer visible, smaller telescopes will easily pick out bright core and elongation of the central bar. Larger aperture will find this one a real treat as the spiral arms curl both over and under the central structure, resembling a ballet dancer “en pointe”. Congratulations! You’ve just observed Caldwell 44.

Until next week? Wishing you clear skies!

Written by Tammy Plotner. NGC 7009 Image Credit: NOAO/AURA/NSF

An Inside Look at Curiosity’s Inner Workings

NASA’s Curiosity rover raised robotic arm with drill pointed skyward while exploring Vera Rubin Ridge at the base of Mount Sharp inside Gale Crater - backdropped by distant crater rim. This navcam camera mosaic was stitched from raw images taken on Sol 1833, Oct. 2, 2017 and colorized. Credit: NASA/JPL/Ken Kremer/kenkremer.com/Marco Di Lorenzo

What makes a rover rove? At the very basic level, it comes down to gears, and all the gears have to made very precisely: there’s no going to Mars to fix anything that doesn’t move just right. This video shows how a gear company in Rockford, Illinois made all the gears for the Curiosity rover — created from titanium — putting in extra hours and effort to get everything just right (they also made the gears for the Mars Exploration Rovers).

It also subtly emphasizes how the money spent on space exploration isn’t just stuffed into a rocket and blasted into space. Almost all of Curiosity’s parts were made from different companies in 33 states in the US; the rest came from companies in partner countries, all which employs hundreds, if not thousands, of people.

You have to bet that every person who created or touched any of the parts — big or small — on Curiosity were just as jazzed as the cheering team at JPL when the rover landed successfully. And that Curiosity is working so well and roving around in Gale Crater has to be a a great feeling of accomplishment and satisfaction, too.
Continue reading “An Inside Look at Curiosity’s Inner Workings”

Beautiful Timelapse: Purely Pacific Northwest

Here’s a wonderful new timelapse from photographer John Ecklund, a photographer from Portland, Oregon. He captures incredible views of the Milky Way over Crater Lake, Mount Hood, Mount St. Helens, the Painted Hills and more, even nabbing a few meteors and a pass of the International Space Station.

“I choose to shoot locations that appeal to the way I would like to interpret the story of time,” says Ecklund. “Here in the Pacific Northwest, there are endless opportunities to document the magnificence of the world around us. I have discovered that when time is the storyteller, a special kind of truth emerges.”
Continue reading “Beautiful Timelapse: Purely Pacific Northwest”

Curiosity Snaps Evocative Self Portrait

Image Cation: Curiosity takes Self Portrait on Sol 32 with the Mars Hand Lens Imager (MAHLI). Image has been rotated up and enhanced by JPL. Credit: NASA/JPL-Caltech/Malin Space Science Systems

Curiosity has snapped an evocative new color self-portrait – and it’s totally unique, being the 1st head shot pose, showing the top of the Remote Sensing Mast (RSM).

You’ll notice it’s a bit dusty ! That’s because it was acquired through the transparent dust cover protecting the high resolution Mars Hand Lens Imager (MAHLI) camera positioned on the turret at the end of Curiosity’s 7 foot (2.1 meter) long robotic arm.

The gorgeous new image was taken on Sol 32 (Sept. 7, 2012) with the dust cover closed over the camera lens and thus provides a taste of even more spectacular views yet to come. The picture beautifully shows the Mastcam, Chemcam and Navcam cameras with the rim of Gale Crater in the background.

The MAHLI image above has been enhanced and rotated – to right side up. See the MAHLI raw image below.

The image was taken as JPL engineers were inspecting and moving the arm turret holding MAHLI and the other science instruments and tools and looking back to image them in turn using the Mast’s cameras.

NASA’s mega Martian rover is pausing for about a week or two at this location reached after driving on Sol 29 (Sept. 2) and will thoroughly check out the robotic arm and several science instruments.

So far Curiosity has driven about 358 feet (109 meters) and is sitting roughly 270 feet from the “Bradbury Landing” touchdown spot as the Martian crow flies.

The car sized robot is about a quarter of the way to Glenelg, the destination of her first lengthy science stop where three different types of geologic terrain intersect and are easily accessible for a detailed science survey using all 10 state of the art instruments including the rock drill and soil sampling mechanisms.

Ken Kremer

JPL’s Torture Chamber for Spacecraft

The Mars Science Laboratory rover, Curiosity being tested under Martian conditions in JPL’s space simulator on March 8, 2011. Credit: NASA/JPL-Caltech

This is a place where engineers inflict all sorts of cruelty. It’s also a National Historic Landmark that is now 50 years old. What is it? The Jet Propulsion Laboratory’s Space Simulator. While the name sounds like it could be a video game or virtual reality trainer, it actually is the place where spacecraft go to see if they’ve the right stuff to survive the harsh environment in space.

Known as the “25-Foot Space Simulator,” it is capable of producing true interplanetary conditions such as extreme cold, high vacuum, and intense solar radiation that is big enough for most spacecraft to fit inside.

Exterior View of Twenty-Five-Foot Space Simulator, in 1983. Credit: NASA/JPL.

Just like the feared simulations that astronauts go through during training for a spaceflight, where Sim-Sups (Simulation Supervisors) conjure up all sorts of scenarios where everything that can go wrong does, the Space Simulator allows engineers to test the complete spacecraft in its flight configuration for most any type of conditions, searching for any problems imaginable.

Over the years spacecraft tested in this facility include the Ranger, Surveyor, Mariner, and Voyager spacecraft and recently, the Curiosity rover took its turn inside this torture chamber.

Doug Smith from Caltech’s Engineering & Science magazine calls it the Ultimate Evil Tanning Bed — expressly designed to deliver a fatal sunburn to anything placed inside.

The Space Simulator chamber is a stainless-steel cylindrical vessel 8.23 meters (27 feet) in diameter and 26 meters (85 feet) high. The walls and floor are lined with thermally opaque aluminum cryogenic shrouds that can deliver a temperature range of -195° to 93° C ( -320° to +200°F) by liquid or gaseous nitrogen. The solar simulation system consists of an array of 37 xenon 20- to 30-kilowatt compact arc lamps that can produce a variety of beam sizes and intensities. If your spacecraft is going to be seared by the Sun at Mercury or be subject to the freezing temperatures in the Kuiper Belt, this facility can test if every bolt, wire, switch, solder point and component can survive.

Once a spacecraft is put inside the chamber, it takes about 75 minutes to get the conditions to the desired levels, and depending on how quickly the engineers want to see how their spacecraft fared, test conditions can be terminated and access provided to the test item in about 2-1/2 hours.

There’s even a setting for geosynchronous orbit simulation that can test declination angle change and much more, all in a vacuum environment.

The facility’s construction started in 1961 and was completed in 1962 at a cost of $4 million.

The first spacecraft to submit to the torture chamber’s extremes was the Mariner 1 spacecraft that was headed to Venus. It passed the torture chamber’s test, but unfortunately the spacecraft had to be destroyed by a Range Safety officer within minutes after it veered off-course during launch on July 22, 1962 due to a defective signal from the Atlas launch vehicle and a bug in the program equations of the ground-based guiding computer. (The Space Simulator just can’t test for problems like that, regrettably.)

But, JPL had already built an identical spacecraft and Mariner 2 launched a month later on August 27, 1962, sending it on a 3½-month flight to Venus.

In the 50 years the Space Simulator has been in operation, every spacecraft built at JPL has been subject to the torture chamber before heading out to the real torture of the harsh space environment.

“It’s a rare thing when a spacecraft goes into the simulator and the engineers don’t learn something important and modify the design to work better,” saids Andrew Rose, the technical manager for JPL’s Environmental Test Laboratory group.

The Curiosity rover inside the Space Simulator. Credit: NASA/JPL

Over the years, the simulator has been upgraded to provide all sorts of environments, and earlier this year, the Curiosity rover took its turn inside, being sealed in a near-vacuum environment, with temperature cooled to – 130° C (-202 ° F) with the giant light panels simulating the sparse Mars’ sunshine and the various radiation intensities found on Mars.

Even more evils await future spacecraft that will be tested in JPL’s Space Simulator.

This article was updated on 9/8/2012

Sources: Caltech, National Park Service

Endeavour to Take to the Skies One Last Time

One of NASA’s 747 SCAs carries Endeavour from Edwards to Kennedy in 2008 following its landing at Edwards to conclude shuttle mission STS-126. (NASA)

Endeavour, mounted atop NASA’s modified 747 Shuttle Carrier Aircraft (SCA), will become the last Space Shuttle orbiter to soar aloft when it departs Monday, Sept. 17, from Kennedy Space Center in Florida on a three-day flight to Los Angeles International Airport.

In cooperation with the Federal Aviation Administration, the SCA is scheduled to conduct low-level flyovers at about 1,500 feet above many locations along the planned flight path, including Cape Canaveral, Stennis Space Center, New Orleans and stopovers in both Houston and Edwards Air Force Base in California.

Read more about NASA’s SCA: “The World’s Greatest Piggy Back Ride”

Flyovers of Sacramento and San Francisco are also planned before landing at LAX on the 20th.

After arrival at LAX, Endeavour will be demated from the SCA and spend a few weeks at a United Airlines hangar undergoing preparations for transport and display. The orbiter then will travel through Inglewood and Los Angeles city streets on a 12-mile journey from the airport to the California Science Center, arriving on the evening of Oct. 13.

See a map of Endeavour’s planned route across LA here.

Beginning Oct. 30, the shuttle will be on permanent display in the science center’s Samuel Oschin Space Shuttle Endeavour Display Pavilion, beginning its new mission commemorating past achievements in human spaceflight and educating and inspiring future generations of explorers.

On August 16 Endeavour was moved from KSC’s Orbiter Processing Facility 2 to the Vehicle Assembly Building, where it’s being housed temporarily until its departure on the 17th. (Photo above at right; read more here.)

On May 16, 2011, Endeavour launched on its final mission, STS-134:

Completed in July 1990, Endeavour (OV-105) was the last shuttle orbiter to be constructed for NASA. Endeavour completed 25 missions, spent 299 days in orbit, and orbited Earth 4,671 times while traveling 122,883,151 miles.

On Twitter and along Endeavour’s route? NASA encourages people to share their shuttle sightings using the hashtags #spottheshuttle and #OV105, Endeavour’s orbiter vehicle designation.

Read more and find the full flight itinerary on the NASA news release.

Is Triton Hiding an Underground Ocean?

Voyager 2 mosaic of Neptune’s largest moon, Triton (NASA)

At 1,680 miles (2,700 km) across, the frigid and wrinkled Triton is Neptune’s largest moon and the seventh largest in the Solar System. It orbits the planet backwards – that is, in the opposite direction that Neptune rotates – and is the only large moon to do so, leading astronomers to believe that Triton is actually a captured Kuiper Belt Object that fell into orbit around Neptune at some point in our solar system’s nearly 4.7-billion-year history.

Briefly visited by Voyager 2 in late August 1989, Triton was found to have a curiously mottled and rather reflective surface nearly half-covered with a bumpy “cantaloupe terrain” and a crust made up of mostly water ice, wrapped around a dense core of metallic rock. But researchers from the University of Maryland are suggesting that between the ice and rock may lie a hidden ocean of water, kept liquid despite estimated temperatures of  -97°C (-143°F), making Triton yet another moon that could have a subsurface sea.

How could such a chilly world maintain an ocean of liquid water for any length of time? For one thing, the presence of ammonia inside Triton would help to significantly lower the freezing point of water, making for a very cold — not to mention nasty-tasting — subsurface ocean that refrains from freezing solid.

In addition to this, Triton may have a source of internal heat — if not several. When Triton was first captured by Neptune’s gravity its orbit would have initially been highly elliptical, subjecting the new moon to intense tidal flexing that would have generated quite a bit of heat due to friction (not unlike what happens on Jupiter’s volcanic moon Io.) Although over time Triton’s orbit has become very nearly circular around Neptune due to the energy loss caused by such tidal forces, the heat could have been enough to melt a considerable amount of water ice trapped beneath Triton’s crust.

Related: Titan’s Tides Suggest a Subsurface Sea

Another possible source of heat is the decay of radioactive isotopes, an ongoing process which can heat a planet internally for billions of years. Although not alone enough to defrost an entire ocean, combine this radiogenic heating with tidal heating and Triton could very well have enough warmth to harbor a thin, ammonia-rich ocean beneath an insulating “blanket” of frozen crust for a very long time — although eventually it too will cool and freeze solid like the rest of the moon. Whether this has already happened or still has yet to happen remains to be seen, as several unknowns are still part of the equation.

“I think it is extremely likely that a subsurface ammonia-rich ocean exists in Triton,” said Saswata Hier-Majumder at the University of Maryland’s Department of Geology, whose team’s paper was recently published in the August edition of the journal Icarus. “[Yet] there are a number of uncertainties in our knowledge of Triton’s interior and past which makes it difficult to predict with absolute certainty.”

Still, any promise of liquid water existing elsewhere in large amounts should make us take notice, as it’s within such environments that scientists believe lie our best chances of locating any extraterrestrial life. Even in the farthest reaches of the Solar System, from the planets to their moons, into the Kuiper Belt and even beyond, if there’s heat, liquid water and the right elements — all of which seem to be popping up in the most surprising of places — the stage can be set for life to take hold.

Read more about this here on Astrobiology.net.

Inset image: Voyager 2 portrait of Neptune and Triton taken on August 28, 1989. (NASA)