Voyage to the Mystery Moon

PBS Airdate: April 4, 2006
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NARRATOR: Saturn: Mysterious, hauntingly beautiful; a swirling ball of gas, embraced by heavenly rings that span over 150,000 miles, circled by more than 40 moons in dizzying orbits; so distant, going there could only be a dream, until now.

NASA and the European Space Agency are teaming up for the most ambitious unmanned space project ever launched. Across more than 2 billion miles, it will battle the bitter cold of space, thread the rings of Saturn, survive the heat of entry and brutal impact of landing, and beam pictures and data back from Titan, its largest moon.

NOVA follows this fantastic voyage to Saturn, on a quest to solve some of the greatest mysteries of this alien world. Up next, Voyage to the Mystery Moon.

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NARRATOR: Saturn, Lord of the Rings, few sights in the solar system are more strikingly beautiful than this celestial sphere, embraced by its majestic rings.

This giant ball of gas, 750 times larger than Earth, visible as a golden star, has captivated our imaginations since we first looked up at the night sky. But it wasn't until 1980, when we were able to get a close-up look at the sixth planet from the Sun.

The Voyager deep space probes flew past Saturn and sent back tantalizing glimpses of this distant world, and Saturn's mysterious rings were seen closer than ever before.

CAROLYN PORCO (Space Science Institute): Voyager got there and found this bewildering array of, of structure in the rings. And people set about trying to explain it right away.

NARRATOR: What are the rings? How were they formed? When were they formed? And how long will they last?

But the rings weren't the only feature Voyager explored. For the first time, detailed images of Saturn's moons were sent back—more than 40 in all, from dozens of minor moons, to one nearly half the size of Earth. It was named after Saturn's mythological brothers, the giant Titans.

Titan was unlike any moon that had ever been seen. It had clouds and an atmosphere 10 times denser than Earth's. Frustratingly, a thick layer of orange haze shrouded its surface.

CHARLES ELACHI (Director, Jet Propulsion Laboratory): We saw this fuzzy ball, and the immediate reaction is, "What's below those clouds?" You know, "What are these clouds made of? What is hidden behind that layer?"

NARRATOR: Whatever was hidden, it had to be a solid body, or else its atmosphere would have long ago escaped into space.

As Voyager confirmed, the atmosphere was nitrogen-rich and included organic molecules, perhaps resembling the atmosphere of the early Earth. Could Titan play a unique role in helping us understand the origin of life on Earth?

JONATHAN LUNINE (University of Arizona): If you look at our solar system, there are only four bodies that have atmospheres and are actually solid bodies themselves: the Earth, Venus, Mars and Titan.

Venus is just so hot that one can melt lead on the surface; there's...there are no organic molecules. Mars today is very cold, very dry, very thin, not a good place for organic molecules. And so we're left with Titan.

NARRATOR: Voyager moved on—out towards Uranus, Neptune and beyond—but Voyager's spectacular images of Saturn and its rings, and this enticing glimpse of Titan, left scientists wanting more.

LARRY ESPOSITO (University of Colorado at Boulder): The combination of the spectacular structure in the rings, the hazy atmosphere of Titan, just left every scientist with a great curiosity to explain those things that we had seen with the Voyager fly-bys. Immediately, there was a feeling that we had to return to Saturn and stay there for a longer time.

NARRATOR: So in 1990, NASA and ESA, the European Space Agency, team up for an unprecedented collaboration, a new mission to Saturn, with a landing on Titan.

To get there, they need to build a spacecraft to travel more than two billion miles, battle the bitter cold of space, thread through the rings of Saturn, withstand the intense heat of entry and the brutal impact of landing, and ultimately beam back pictures and data.

Their odds of success seem about as likely as throwing a basketball from NASA's launch site at Cape Canaveral, Florida, through a hoop in ESA's command center in Germany, without touching the rim.

The spacecraft they design to accomplish this mission, they name Cassini, after the 17th century astronomer who discovered gaps in Saturn's rings.

Built by NASA's Jet Propulsion Laboratory, the Cassini deep space probe carries an amazingly complex array of instruments. The eyes of Cassini are two sophisticated cameras.

CAROLYN PORCO: One is a very long focal length, very high resolution, but you get little postage stamp-like coverage. And so you want to also carry a camera with a larger field of view, shorter focal length, that covers a greater amount of territory, so you can put your little postage stamp coverage in context, in geological context.

NARRATOR: Cassini is also loaded with a powerful radar, designed to punch through Titan's hazy atmosphere. And that's not all. Riding aboard Cassini on this seven-year mission is a small probe, built by the European Space Agency. Named Huygens, after the astronomer who discovered Titan in 1655, this probe is designed to actually land on the moon's surface. It will see, sniff, touch and listen to the mysterious moon, radioing back images and data to orbiting Cassini, under conditions that no one can precisely predict.

RALPH LORENZ (University of Arizona): The atmosphere could have been thicker than we thought or thinner than we thought, warmer or cooler. We had no idea what the surface was, so there was no guarantee that the probe would keep working after it hit the ground.

NARRATOR: The engineers need to make sure that Huygens is tough enough for the job. Every aspect of the super sensitive probe's design and construction must be put to the test.

When the probe slams into Titan's atmosphere, it will produce temperatures of over 20,000 degrees Fahrenheit, more than twice the surface temperature of the Sun.

And it's this heat shield that is designed to withstand it.

If the probe survives the heat of entry, successful landing will depend on the precise opening of three small parachutes. Packed for seven years, these parachutes have to deploy, unfold and inflate in sequence or the mission will be lost.

During the two-and-a-half-hour descent, specially designed onboard cameras will act as the eyes of the probe. It is these cameras that will send home the first glimpse of Titan's surface.

For Huygens' imaging specialist, Martin Tomasko, it is imperative that his cameras don't miss a thing.

MARTIN TOMASKO (University of Arizona): What we're trying to get is kind of the skydiver's eye view, as if you were outside the probe and falling down through the atmosphere. We don't want to land near some interesting object like the Grand Canyon and not know it's there. To see through the haze has been notoriously difficult. We hope that our big advantage is that we'll fall through the haze, and eventually we'll be under most of the haze and be able to see the surface that much more clearly.

NARRATOR: After descending through the orange shroud, the climax of the mission is touchdown on Titan's surface.

JOHN ZARNECKI (The Open University): We set up a facility in the lab that would enable us to simulate what would happen when Huygens hit the surface of Titan.

This device called a penetrometer, will measure the force of first contact. You get a very different signal if you strike, for example, a sheet of solid ice, if you hit semi-compacted snow, if you, if you struck a liquid—if you landed in a lake, for example.

You know, we used to joke and say we would either thud, squelch or splash down, and that really is quite a good description, because it could have been any of those scenarios or a mix of them.

NARRATOR: By 1997, the Cassini-Huygens spacecraft is built and assembled, but there is one major challenge: together, their weight is massive.

ROBERT MITCHELL (Cassini Program Manager, Jet Propulsion Laboratory): The Cassini spacecraft is the largest interplanetary satellite that NASA has ever built and launched.

NARRATOR: The big problem is how to get this six-ton leviathan into space. The most powerful rocket on Earth, the mighty Titan IV, is selected for launch, delivering over 3.4 million pounds of thrust. But even this will not be enough. For not only does Cassini have to break free from Earth's gravity, it has to travel almost a billion miles to Saturn, on a small amount of fuel.

The only way for Cassini to make the journey is to pick up additional energy from a flight path that takes advantage of an unusual convergence of the planets.

LARRY ESPOSITO: The energy that we needed to get out in the solar system, out to the planet Saturn had to be supplemented by...partially provided by gravitational encounters with the planets. The important thing is to gather energy from the gravity of the planet you're flying by.

NARRATOR: First, Cassini will be routed via the Earth's nearest neighbor, Venus. This planet's gravitational pull will accelerate Cassini, increasing its speed by over 8,000 miles per hour, but this still will not be enough. Cassini will need to return for a second boost from Venus. Then it's the Earth's turn, accelerating Cassini with a fling out towards its next rendezvous, Jupiter. Eventually, the spacecraft will clock up a speed of 50,000 miles per hour before reaching its final destination -- Saturn. That's the theory, but will it work?

October 15, 1997: With the planets in perfect alignment, from NASA's launch site at Cape Canaveral, in Florida, Cassini blasts into the night sky.

RALPH LORENZ: It sort of lit this cloud up, like a Chinese lantern, from within. It was quite spectacular and, and you just think, "Wow, you know. It's out of our hands now."

NARRATOR: The seven-year journey, covering 2.2 billion miles in all, begins. With Cassini-Huygens now en route to Saturn, scientists will soon have the opportunity to explore the mystery of Saturn's majestic rings and its enigmatic moon, Titan.

Two years into its journey, the spacecraft loops around Venus a second time and swings back past the Earth. Here, the JPL scientists check out Cassini's high-power radar. It scans a huge swath of South America, and everything is in working order. The radar seems to be operating flawlessly.

Next, they perform a simulation to test the radio link between Huygens and Cassini.

JOHN ZARNECKI: The Huygens probe itself doesn't have enough power, and it doesn't have a large enough dish to transmit its data, the scientific data that it collects on Titan, directly back to the Earth. So what will happen is that it uses the Cassini spacecraft as a data relay.

NARRATOR: The test is to make sure that Cassini is receiving all the data from Huygens, but when the results come back, they are alarming.

JEAN-PIERRE LEBRETON (Huygens Mission Manager, European Space Agency): We were expecting to receive all the simulated data. Unfortunately, we did not receive very many of those data. We lost, well, it's...we lost maybe 90 percent of the data, sometimes even all of the data.

NARRATOR: If Cassini fails to receive the data from Huygens, then when the probe descends to Titan, there will be no results, no pictures, nothing. A crucial part of the mission will be lost.

Huygens' European team calls a meeting to discuss the situation. As one of NASA's imaging specialists for Huygens, Martin Tomasko cannot believe what he is hearing.

MARTIN TOMASKO: They said, "We've performed the test, and we didn't get any signal, but the test accomplished all of its objectives." And some of us were sitting around the table saying, "What? What exactly are you trying to sell us?" You know, you've accomplished the objectives of conducting the test, but you've actually succeeded in proving the thing is not going to work.

NARRATOR: Six months of painstaking detective work finally pinpoints the problem. When Huygens is descending to Titan, Cassini will be speeding away from it at 12,000 miles per hour; they will no longer be able to communicate on the same frequency.

JOHN ZARNECKI: It was enough to, essentially, put the link between the two out of alignment. It was as if Huygens was transmitting on, on Radio One, on one frequency, and Cassini was receiving on Radio Two, a slightly different frequency, so this was potentially disastrous.

NARRATOR: Retuning the receiver is impossible. Cassini is out in space, over 300 million miles away.

JEAN-PIERRE LEBRETON: There was no way we could repair, so we had to find a new mission scenario which would, which would allow us to live with this problem but still to recover the, the whole mission.

NARRATOR: After months of research, they devise an ingenious plan. Although they can't retune Cassini's receiver, they can shift the signal it is picking up by using a basic principal known as the Doppler Effect.

If they can slow Cassini down, it will receive the radio waves that Huygens is sending at a lower frequency, solving the problem.

JEAN-PIERRE LEBRETON: All in all, it took us six months to find a solution, but it took us two years to design all the detail of the solution and to test it. We are not going to lose any science, so it's a very successful recovery.

NARRATOR: Both teams are now hopeful that Huygens has a good chance of sending back its precious data, when it finally reaches Titan.

By the year 2,000, Cassini is now a billion and a half miles out in space and arrives at Jupiter, the giant of the solar system. With a planet twice as massive as all the others combined, Cassini's cameras face their biggest test yet.

Jupiter's majesty is revealed as never before. Its swirling gaseous atmosphere is seen with breathtaking clarity. But Cassini has to move on across another 500 million miles of space before it reaches its final destination.

For imaging team leader Carolyn Porco, the Jupiter pictures are a triumph. But her true goal is the planet she has devoted her career and heart to studying, Saturn.

CAROLYN PORCO: To know that we can know so much about our solar system and about our cosmos, for me, makes life meaningful. It's very much like being in love. It's very much that kind of a relationship, where you want to know more and, and you want to be one with the person you're in love with or the topic that you're studying. It's, it's, it's kind of this...it's a connection. It's really a connection. And for me, it's, it's like being allowed a glimpse of the miraculous.

NARRATOR: Spring of 2004: Cassini is closing in on Saturn, but just before contact, mission planners calculate a precise course to send the spacecraft past Phoebe, Saturn's outermost moon.

Until now, all that scientists had seen of Phoebe is this picture, taken by Voyager, 23 years ago. But this time Phoebe is in the cross hairs of Cassini's powerful cameras. Picture after picture returns with astounding detail.

CAROLYN PORCO: We buzzed Phoebe, okay? We came within 2,000 kilometers of its surface. You could reach out and touch it, is what it looked like. So it's very exciting. We saw features that were, were 30 meters across.

NARRATOR: The images of Phoebe reveal an ancient surface, pitted with craters created over billions of years. But Phoebe is just an appetizer, a taste of what is to come.

June 2004: At the Jet Propulsion Laboratory in California, NASA's team has piloted the Cassini spacecraft across 2.2 billion miles of space and is still right on target, fast approaching one of our solar system's greatest enigmas, the rings of Saturn.

Very little is known about them.

CAROLYN PORCO: The questions that we scientists have about Saturn's rings are the questions that an ordinary person might be moved to ask when first seeing them, you know? "What caused them? How did they get there? How long have they been around? How long are they going to last?"

NARRATOR: Answering these questions is one of Cassini's prime objectives. A good opportunity for close-range observation will come as mission control maneuvers Cassini into orbit around Saturn, because that means passing right through the rings.

Voyager revealed that the rings are made up of rock-hard ice, ranging in size from a grain of sugar to a large house. The rings, just 300 feet thick and a vast 38,000 miles wide, are chaotic and dangerous.

LARRY ESPOSITO: All the ring particles, billions and billions of them, are in orbit around the planet Saturn, and they're moving at quite a clip, something like 10 kilometers per second—faster than a high-speed bullet. If you were in Saturn's rings, you would be in a mass of particles that were bumping into each other and rolling over each other. If you were a ring particle, you would get bombarded from one side and then from the other, as one particle bounced off of another, all around you.

NARRATOR: Entering directly into the rings would be suicide. But NASA's JPL team has a plan. They calculate a course for the spacecraft through a 15,000 mile gap in Saturn's rings. Even so, with one small miscalculation, Cassini could be torn apart.

LARRY ESPOSITO: Even a very small particle could be the end of Cassini. If it hits a particle as small as a grain of rice, that would be enough, because of the high speed at which it's moving, to end the mission.

NARRATOR: But particles from the rings are not the only danger that Cassini faces. It also has to slow down. That means firing up its main engine. Any malfunction, and Cassini will simply fly past Saturn, lost forever in the void of space.

CHARLES ELACHI: That engine had not been used very frequently over a period of seven years; that makes you nervous. You know, it's like you have a car, a brand new car that you put in the garage, and every once in a while, you turn it on. And then you have an emergency, and you get in the car, and you turn it on—it better work.

NARRATOR: June 30, 2004: The press gathers at JPL for news of the most critical part of the seven-year trek across the solar system.

The ring insertion maneuver begins at 7:36 p.m. First, Cassini rotates to use its giant antenna as a shield to protect it when it passes through the gap in the rings.

CAROLYN PORCO: You can image how anxious some of us were, knowing that it all hinged on one 90-minute period, where we would have to perfectly just slip into orbit.

NARRATOR: All eyes are on a radio signal being sent by Cassini's auxiliary transmitter. If the signal continues, then flattens out at the bottom of the graph, they'll know that Cassini survived. A $3.2 billion mission and 14 years of work all hinge on this one moment.

DOUG JOHNSTON (NASA Radio Science Subsystem Engineer): The Doppler has flattened out.

NARRATOR: Cassini has arrived. When the images return, Saturn is revealed as never before.

CAROLYN PORCO: I just don't know what to say. I'm kind of speechless.

CHARLES ELACHI: Oh, absolutely exciting! This is the culmination of 22 years of effort, and just seeing the Lord of the Rings in its big glory. We are amazed about the detail we are seeing and the sharpness in the rings. You wait years to have this kind of a moment.

NARRATOR: These remarkable images begin to provide new clues to some of Saturn's oldest mysteries: What are the rings made of? And when were they formed?

Since Voyager, scientists have known the rings are composed of rock-hard ice. Cassini is revealing far more about the composition of the ice.

LARRY ESPOSITO: The rings are made of ice, just like the stuff you've got in your ice cube trays, and almost a hundred percent pure water ice with some small contaminants.

NARRATOR: These contaminants, minute traces of dust that come from meteors, are the key to finding out the age of the rings. The basic principle is simple: the more contamination, the longer the rings have been bombarded and the older they are.

LARRY ESPOSITO: The pollution is sort of a like a clock, because we're pouring material in on top of the rings, and it's dark, non-icy material, so the level of darkness in the rings tells us something about their age.

NARRATOR: To discover the level of pollution in the rings, Cassini is equipped with a spectrometer that translates chemical composition into vivid color images. What they show is surprising.

LARRY ESPOSITO: The spectacular range of structure in the rings with reds and blue and aquas, that was something that was completely unpredictable.

NARRATOR: The images show cleaner ice in shades of blue, the heavier contamination in red. So it appears that the inner rings are older and that the outer rings have been made more recently.

LARRY ESPOSITO: It's definitely the case that there's a gradient in composition across the rings, so that the rings are less icy on the inside and more icy on the outside. As we go to the outside, the particles become younger and fresher.

NARRATOR: These new spectrometer images seem to suggest an intriguing possibility that perhaps Saturn's rings are still being formed. But beyond the riddle of the rings, another chapter in Cassini's voyage is about to begin, its encounter with Titan, Saturn's mystery moon.

Christmas Day, 2004: Mission control navigates Cassini into a safe orbit around Saturn. Now they give the command to release the landing probe. They fire three explosive bolts, and Huygens pushes away from Cassini.

In 1980, Voyager confirmed that Titan is one of only four bodies in the solar system that are solid and have a substantial atmosphere, the conditions that gave rise to life on Earth. Since then, what's beneath Titan's orange veil has captivated scientists' imaginations.

CAROLYN PORCO: Whenever we humans think that we might be approaching something that is vaguely similar to Earth, we get very excited about it. The prospect of something familiar, but yet so distant, and so strange is, is a very exciting combination.

NARRATOR: Billions of years ago on Earth, it's thought that simple molecules may have spontaneously combined to form more complex chemicals that became the building blocks of life. But Earth today is teeming with life; it has taken over the entire planet. This makes Earth problematic for studying the leap from chemistry to life.

JONATHAN LUNINE: It's very difficult to use the Earth as a laboratory for understanding how life began. Life eats all of the organic molecules that are present on the Earth today. If we go to the laboratory and try to simulate how life began, we have limits on time and space. A laboratory experiment might be this big; a laboratory investigator might work for two or four or 10 years perhaps, no more than that. We really need a place where organic evolution is happening on a planetary scale, over billions of years, but is not being ruined by the presence of life.

NARRATOR: For years, scientists have been looking for a place that has a similar primordial chemistry to early Earth. Could Titan be that place? Based on data from the Voyager mission, scientists know the atmosphere of Titan contains nitrogen and methane, made of carbon and hydrogen.

JOHN ZARNECKI: It's dominated by nitrogen, but it has methane and a whole range of hydrocarbon gases, gases made of carbon and hydrogen.

NARRATOR: Scientists also know of one other ingredient that's crucial for making the leap from chemistry to life.

JONATHAN LUNINE: If we were to apply what is the essential ingredient of all life, liquid water, then we may well make some amino acids, which are the building blocks of life.

NARRATOR: But how could liquid water exist on Titan, with a surface that's nearly 300 degrees below zero?

Control of Huygens is based at the European Space Agency command center in Darmstadt, Germany. Finally, the team is about to find out what lies hidden beneath the orange veil.

On January 14, 2005, 150 miles above Titan, Huygens slams into Titan's atmosphere. The time has come to witness Huygens' historic descent to Titan's surface.

JOHN ZARNECKI: The emotion in that control room, I mean, it was absolutely tangible.

NARRATOR: But the scientists will have to be patient. It's still a long wait before any data is received back at Mission Control.

JOHN ZARNECKI: The fact that all the data was transmitted to Cassini—Cassini would then store the data and only some hours later send it back to Earth—meant that there was a delay time of several hours. So it was sort of unreal, knowing that things were happening. We didn't know if they were good things or bad things; they were happening, but we knew nothing about it.

NARRATOR: Now, operating on automatic, one minor malfunction can terminate the whole operation.

MARTIN TOMASKO: We have to have a heat shield that works and protects the probe from burning up during the entry. We have a series of explosive bolts that has to fire to release the heat shield and deploy the parachutes. They all had to work perfectly. If you make a mistake there, you lose the rest of the mission.

NARRATOR: Everything has to be relayed from Huygens to Cassini then back to Earth, so they are not expecting to receive any news of Huygens' fate for hours. But then, they get a surprise. They pick up a signal, not from the orbiting mother ship, but direct from Huygens itself.

LEONID GURVITS (Project Manager, Huygens Very Long Baseline Interferometry [VLBI]): A few minutes ago we have received confirmation of the carrier signal from Huygens.

JEAN-PIERRE LEBRETON: It tells us that the probe is alive, the entry has been successful, we are under parachute, and the probe is transmitting.

NARRATOR: In Green Bank, West Virginia, the giant 360-foot dish of the Robert C. Byrd radio telescope is pointing directly at Titan. It is listening for even the faintest of signals.

LEONID GURVITS: We were kind of eavesdropping on the conversation between Huygens and Cassini. So the strength of the signal which we deal with is practically the same as the strength of the signal from a mobile phone, but located, not in your pocket or my pocket or somewhere nearby, but at a distance of one billion kilometers, on Titan.

NARRATOR: Receiving a radio signal from Huygens is the first indication that all is going according to plan.

JOHN ZARNECKI: This is absolutely fantastic news. It's like hearing the ringing tone on the phone. It tells us the phone is working. There's no information on it yet but it's, it's absolutely fantastic.

NARRATOR: The radio signal from Huygens is too weak to relay any scientific data. For that, Mission Control will need to wait for Cassini.

JOHN ZARNECKI: We were told to expect the data at 15:24, Central European Time, in the afternoon. And, I remember, 15:24 came and went, and we were looking at the screens. We knew where the numbers should have appeared and absolutely nothing.

MARTIN TOMASKO: And we're thinking, "How is it possible that everything could have worked well on Huygens and we wouldn't get data?" And we say, "Oh yes, it could have worked perfectly on the probe, but if the orbiter didn't receive it, this all could, we could still lose the whole thing."

JOHN ZARNECKI: You know, the minutes ticked by, it got quieter and quieter; we were looking at each other.

MARTIN TOMASKO: And two minutes goes by, and four minutes goes by, and six minutes goes by, and there's still nothing. And we're all just shaking our heads, and there's just gloom, absolute gloom over the whole audience.

JOHN ZARNECKI: 15:30—so this was six minutes after we were led to believe the data would come through—I can remember looking at one particular screen, and where there was a large gap before, suddenly a whole column of green figures appeared. And this was the first science data from Huygens.

NARRATOR: Finally, the Cassini mother ship is sending all of Huygens' scientific data back to Earth. Although the probe actually landed on Titan's surface some hours ago, only now can the scientists begin their own descent onto Saturn's mysterious moon. But for Martin Tomasko, the first images he receives are murky.

MARTIN TOMASKO: We saw a lot of inside of the milk bottle pictures in the beginning, you know? It's just all washed out. Somewhere between 50 and 70 kilometers, we thought we'd come out through the bottom of the haze, have clear views of the surface. Well, that was not the case.

NARRATOR: If the haze continues all the way to the ground, Huygens will fail to obtain crucial photographic data.

MARTIN TOMASKO: We finally got close enough to the ground to see the ground through the haze, at 30 kilometers altitude only, and, and that was, that was beautiful. That was, that was the first stuff we saw.

NARRATOR: After decades of wondering what the surface of Titan looks like, scientists now get their first glimpse beneath the haze and discover a surprisingly Earthlike geography.

RALPH LORENZ: I sort of looked, looked up and there was this projection screen, and the first thing you see is these river valleys everywhere, and you think, "Wow!"

MARTIN TOMASKO: All of a sudden, you could see these drainage channels, and it seemed to come together over, over the highlands, over the bright material. And when you got to the dark material, there was this low region that looked like a flat lakebed. You know, after all this you go down through the haze, and there it is, this dry riverbank that looks like a backyard in Arizona somewhere.

NARRATOR: Having survived the descent unscathed, the most anticipated moment in the entire mission is the touchdown on Titan.

Upon contact, Huygens' penetrometer reveals the nature of the surface at the landing site.

JOHN ZARNECKI: We're sitting on icy grains, which have the consistency of sand. It's sort of gravel, fine gravel you might see on a river shore or on a dried up lakebed.

NARRATOR: When the probe, hot from the friction of entry, contacts the icy surface, the surface melts and Huygens' chemical sniffer detects a curious spike.

JONATHAN LUNINE: The amount of methane that the chemical sniffer was detecting jumped very quickly, and it jumped up in such a way that there must have been, underneath this warm probe, a pool of liquid methane.

NARRATOR: From over a billion miles away, Huygens' landing confirms what scientists had suspected, that not only its atmosphere, but also the surface of Titan contains the organic compound, methane.

It has been nearly 25 years since Voyager took this first hazy image. Now, with Huygens, comes this first close-up image from the surface of Titan.

MARTIN TOMASKO: Can you show the first picture, cropped 448 on the screen please? And we'll see Titan unveiled, as we haven't seen it before.

NARRATOR: Huygens' camera reveals its landing site as a dry riverbed, with rounded pebbles made of ice, beneath an orange sky.

JOHN ZARNECKI: If that image alone was the only piece of data produced by the Huygens' mission, I would say that it was worthwhile.

NARRATOR: But that image is not alone. Others reveal networks of rivers, hills, and valleys, and a surface made of damp sand, a mixture of icy pebbles and liquid methane.

Huygens, mankind's furthest outpost in the solar system, transmits data and images for 180 minutes, then dies. But Cassini, its mother ship, lives on. From its orbit around Saturn, it peers down as it passes over the mystery moon and continues to reveal a whole new picture of Titan.

JONATHAN LUNINE: Cassini was definitely not just about getting Huygens to Titan; Cassini was about exploring Titan. The orbiter has been unveiling Titan in, in its own very special way.

NARRATOR: Using remote sensing, infrared and radar imaging, Cassini pierces through Titan's thick haze and reveals that Titan's surface has many familiar Earthlike features.

JOHN ZARNECKI: We're seeing river channels, we're seeing erosion. But, whereas on Earth we're talking about rocks and liquid water, on Titan it's ice and liquid methane.

NARRATOR: This is a world suffused with methane, raining down from the atmosphere, carving out hills and valleys, eroding ice rocks and finally sinking into the sandy surface.

In addition to erosion from methane rivers, Cassini reveals that Titan's surface appears to have also been modeled by lava flows. But this is lava as never before seen.

ROBERT BROWN (University of Arizona): We saw some structures on the surface of Titan that looked very curious; they looked like volcanoes. But these are very different than the kinds of volcanoes that you would expect to see on Earth. These are what we call cryovolcanoes.

NARRATOR: Volcanoes on Earth erupt molten rock, but the cryovolcanoes on Titan's frozen world erupt something altogether different.

ROBERT BROWN: The working fluid for a volcano on Titan is water, but it's water mixed with ammonia. And the result of that is it lowers the freezing temperature of water from zero degrees centigrade, down to as low as minus-100 degrees centigrade.

NARRATOR: If you could climb up to the summit of a volcano like this and look down in its caldera, you would see a very sticky viscous fluid that's literally oozing out of the ground and flowing down the flanks of this volcano, much like a very, very fast glacier.

Methane in its rivers, nitrogen in its atmosphere and now the presence of this bizarre form of water—Huygens and Cassini have made a remarkable discovery: Titan may, indeed, have all the key ingredients to form the basic building blocks of life.

JONATHAN LUNINE: These things all operate on Titan, under exotic conditions, in much the way that they operate on the Earth, but there's no life on Titan. And so it's telling us that the basic conditions for a world where life can begin could occur in many places, but if temperatures are too cold, the whole process is going to be slowed down. And so, we're looking at an Earthlike world where the chemistry has just not gotten to the point yet.

NARRATOR: In these oozing volcanoes, it could be that organic molecules are too frozen to combine and form the more complex molecules of life. But beneath the surface, where it's warmer, there could be living microbes feeding on organic molecules and producing some of the methane in Titan's atmosphere.

Cassini will orbit Saturn for years to come, searching for more clues to the oldest mysteries of the Lord of the Rings, the age of the enigmatic rings and how they were formed. And the spacecraft will continue to fly by Saturn's many moons.

Recently, Cassini revealed that Saturn's fourth largest moon, Enceladus, is erupting plumes of icy crystals. This suggests that pockets of water may be just beneath the moon's surface, adding Enceladus to the short list of places in our solar system that are potentially suitable for life.

And Cassini will continue to visit Saturn's largest moon, a world both alien and Earthlike, a place that still holds many secrets: Titan, the mystery moon of Saturn.

On NOVA's Web site, hear intriguing sounds from the mission, explore the icy geysers of Enceladus, and take your own voyage to the mystery moon. Find it on PBS.org.

Educators and educational institutions can order this, or other NOVA programs, for $19.95 plus shipping and handling. Call WGBH Boston Video at 1-800-255-9424.

NOVA is a production of WGBH/Boston.

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PRODUCTION CREDITS

Voyage to the Mystery Moon

Written and Produced by
William Hicklin
Paul Olding

Produced for NOVA by
GaryGlassman

Edited by
Rick Widmer
Alice Forward
Simon Holland

Archival Research
Tricia Power
Emma Bolton

Research
Sophie Wallace-Hadrill

Associate Producer
Cass Sapir

Production Team
Gezz Mounter
Leigh Gibson
Titilayo Adegbite

Production Coordinators
Nicola Frost
Sias Wilson

Production Managers
Yolanda Ayres
Peter Badcock

Narrated by
Neil Ross

Camera
Will Edwards
Rob Franklin
Graham Barnes

Sound Recordists
Chris Gibbons
Peter Sainsbury
Tim Humphries

Animation
The Post Lounge
Jason White

Research Interns
Bryan Chang
Kristen SaBerre

Online Editor & Colorist
Mark Steele

Audio Mix
John Jenkins

Special Thanks
NASA/Jet Propulsion Laboratory
SpecTIR
ESA
Dr. Chris Riley
Goddard Space Flight Center
Imperial College London
National Radio Astronomy Observatory
West Virginia Public Broadcasting

Archival Material
NASA
ESA
Simon Carroll Archive

Deputy Editor for Horizon
Jonathan Renouf

Executive Editors for Horizon
Andrew Cohen
Matthew Barrett

NOVA Series Graphics
yU + co.

NOVA Theme Music
Walter Werzowa
John Luker
Musikvergnuegen, Inc.

Additional NOVA Theme Music
Ray Loring

Post Production Online Editor
Spencer Gentry

Closed Captioning
The Caption Center

NOVA Administrator
Dara Bourne

Publicity
Eileen Campion
Olivia Wong

Researcher
Gaia Remerowski

Senior Researcher
Barbara Moran

Production Coordinator
Linda Callahan

Unit Managers
Lola Norman-Salako
Carla Raimer

Paralegal
Richard Parr

Legal Counsel
Susan Rosen Shishko

Assistant Editor
Alex Kreuter

Associate Producer, Post Production
Patrick Carey

Post Production Supervisor
Regina O'Toole

Post Production Editor
Rebecca Nieto

Post Production Manager
Nathan Gunner

Supervising Producer
Stephen Sweigart

Producer, Special Projects
Susanne Simpson

Coordinating Producer
Laurie Cahalane

Senior Science Editor
Evan Hadingham

Senior Series Producer
Melanie Wallace

Managing Director
Alan Ritsko

Senior Executive Producer
Paula S. Apsell

Produced for NOVA by Providence Pictures, Inc.

Titan: A Place Like Home © 2005 BBC

Saturn: Lord of the Rings © 2004 BBC

Voyage to the Mystery Moon Additional Material © 2006 WGBH Educational Foundation

All Rights Reserved