Transcript – Cassini's Infrared Saturn, Director's Cut

 

Michael Flasar: My name is Michael Flasar and I am the principal investigator of the Cassini Composite Infrared Spectrometer, otherwise known as CIRS.

 

Conor Nixon: My name is Conor Nixon. I'm a planetary scientist here at NASA Goddard Space Flight Center, and I study Saturn and its amazing system of moons and rings using the Composite Infrared Spectrometer on the Cassini spacecraft.

 

Carrie Anderson: My name is Carrie Anderson. I work at NASA Goddard Space Flight Center and I'm a co-investigator on the CIRS team.

 

Michael Flasar: Cassini is the mission that was to study the Saturn system, and has studied the Saturn system. It consisted of a spacecraft that orbits Saturn and studies all the other satellites in the system, and the rings. But it also had a probe, and its probe landed on Titan.

 

Carrie Anderson: Before Cassini, the previous flagship was Voyager. That flew by the Saturn system in 1980, Voyager 1. In 1981 was Voyager 2. Those were just flyby missions. Cassini went into orbit around Saturn, which was the first time, very historical, this had never happened.

 

George Diller off-screen: And liftoff of the Cassini spacecraft on a billion-mile trek to Saturn!

 

Conor Nixon: The spacecraft launched in 1997 and after a long, seven-year cruise, it arrived at Saturn, did a dramatic entry burn into orbit around Saturn, and then commenced a wondrous, thirteen-year mission to explore the entire system of moons and rings around Saturn.

 

Conor Nixon (continued): CIRS is Cassini's Composite Infrared Spectrometer, built at NASA Goddard Space Flight Center, and this instrument is designed to measure thermal infrared radiation, or heat, and split it up into different wavelengths and measure the intensity of each one of these wavelengths.

 

Michael Flasar: The other thing is, it's a chemical assayer. These molecules in the atmosphere, ethane, methane, hydrogen, these molecules have distinct signatures in the spectrum. They're their fingerprints.

 

TEXT ON SCREEN: After arriving in 2004, Cassini began observing Saturn and its moons in the infrared using CIRS. CIRS carried out over 1.4 million commands and collected terabytes of data and image products. Here are some of the instrument's Greatest Hits.

 

Conor Nixon: So in 2010, there was a giant outburst in Saturn's northern hemisphere. A giant storm eruption occurred, and eventually this spread around to encircle the entire globe at a latitude width about the extent of North America.

 

Carrie Anderson: Imaging first picked it up, and it was, it was massive. From north to south it spanned about nine thousand miles. CIRS saw temperature increase like we've never recorded before.

 

Conor Nixon: CIRS, looking with its thermal infrared eyes, was able to see two bright beacons of hotspot temperatures shining about 150 degrees brighter than the surroundings.

 

Michael Flasar: We, all of a sudden we had these two bright spots. After a month or two they merged, which was kind of curious, and then it persisted for another two years. In fact, it persisted longer than the tropospheric storm.

 

Conor Nixon: Typically on Saturn these occur about every twenty to thirty years, this is the sixth one that's been seen since 1876. And Cassini was lucky enough to be there at the right place at the right time to see this storm eruption.

 

Carrie Anderson: Mimas and Tethys are two of, I believe the last count was about sixty-two moons that Saturn has, and these are examples of these icy satellites, two of Saturn's icy satellites. When you just take images with Cassini they look normal. With Mimas it looks like the Death Star, you know, and then you superimpose the thermal maps from CIRS on it. And when you superimpose the thermal maps, it looks like Pac-Man.

 

Michael Flasar: Mimas was an example where we saw very warm temperatures surrounding a very cold region, as if it was going to, you know, chomp it up. Turns out the explanation is kind of, is interesting.

 

Conor Nixon: The way these are created is due to their orbital orientation as they go around Saturn. They have a leading side, which is always towards the front of its motion, and a trailing side. And the leading side is intensely bombarded by radiation from Saturn's magnetosphere.

 

Carrie Anderson: So the high-energy particle bombardment is causing this fluffy surface, this icy, fluffy surface, to be packed down to a very hard, solid ice surface, and you're changing the way now the surface can heat up and cool down over the course of a day for these moons.

 

Conor Nixon: When we look at these in infrared we see a cooler region on the leading hemisphere, and a warmer region surrounding it. And this gives the exact appearance of these Pac-Man features that we so know and love.

 

Carrie Anderson: Enceladus is a very small, icy moon of Saturn. It's about three hundred miles in diameter. It's a moon that we weren't expecting to see a lot from, and it's had a huge impact on the Saturn system.

 

Conor Nixon: Previously, we had hints that this moon may be active stretching all the way back to the Voyager mission. But when Cassini arrived, it was able to detect curtains of icy material venting into space. Then using the CIRS instrument, we were able to zoom in on the south pole, and see the south pole was much warmer than we expected.

 

Michael Flasar: The pattern of temperatures on Enceladus did not match a simple inert body absorbing sunlight and reradiating it. The question was what to make of all this. The community decided it must be tidal friction, tidal heating, as Enceladus orbits Saturn.

 

Conor Nixon: This tells us that Enceladus is being heated up by the action of Saturn's gravity. Inside Enceladus, we now know that there's a liquid water ocean, and it's this ocean which is venting through these cracks into space.

 

Carrie Anderson: Throughout the mission, we've learned that it has a subsurface, liquid-water environment. And with NASA, when you see liquid water, it's "Follow the water," because that's important for life.

 

Michael Flasar: Titan was one of the major objectives of Cassini. We knew from Voyager that Titan was an organic molecule paradise, it just was filled with organic molecules. But maybe one of the key things about Cassini was, instead of a flyby past the Saturn system, Cassini hung around for thirteen years. And during that time, even though we were orbiting Saturn, we flew by Titan a hundred and twenty-five times.

 

Carrie Anderson: Titan, at visible wavelengths, looks like as everyone has seen, a orange-y, hazy moon. When Cassini was built, we put on spectrometers that could see to longer wavelengths, outside of the eye's visible range. And so we removed the veil of this smog, we peeled it back. Lo and behold, we saw this amazing, very active surface. River channels, and dunes, and we found polar lakes. And we never saw this before because we couldn't penetrate this very opaque, hazy atmosphere.

 

Conor Nixon: In 2013, we made a fascinating discovery about Titan's atmosphere. We discovered a new molecule, which hadn't been previously detected. And this is called propylene, and this molecule, on the Earth, serves a variety of purposes. In fact, it's one of the raw ingredients that we use to make a type of hard rubbery plastic commonly known as Tupperware, which we use in our lunch boxes. And it was really incredible to find this molecule just floating around in Titan's atmosphere. Going all the way back to the Voyager mission thirty-two years earlier, we'd seen a lighter molecule and a heavier molecule in the same chemical family. But there was a gap at a particular molecular mass, a particular size of molecule that we just couldn't see anything in. So this discovery, using CIRS, filled in this puzzle piece, which had been completely outstanding for about thirty-two years.

 

Conor Nixon (continued): Cassini's Grand Finale is now underway as we dive repeatedly over the planet's north pole, and through the gap between the planet and its innermost rings. We're making gravity measurements and magnetic field measurements, and this is information that we didn't get earlier in the mission so in many ways it's like having a whole new spacecraft mission. Finally, on the very last orbit, Cassini will go closer to Saturn and eventually burn up in its upper atmosphere. The spacecraft will disintegrate and become a permanent part of Saturn.

 

Michael Flasar: It's a bittersweet moment for us. We're so used to doing Cassini, we'll miss it. As far as what CIRS has accomplished, the excitement about the Enceladus south pole has to rank high. The complex dynamics of Saturn and its storms. Titan, just being able to see Titan. The point is that if you don't go up close and take the data, you get nothing. If you do take the data, there's no guarantee you're going to solve all the problems, but on the other hand at least you've made the effort to acquire something and ask other questions.

 

Carrie Anderson: This mission and the amount of data it's recorded goes beyond just one object. Titan has always been my true love, but I also have learned to really appreciate other moons in Saturn's system, for example, Iapetus. It has this amazing dark-leading hemisphere, but its trailing hemisphere is bright like snow. It's been called the yin and yang moon. One of the moons called Pan, it's embedded in Saturn's A-Ring, and it causes this gap. Pan looks like a flying saucer. These kind of things, you can't have unless you're in orbit around such a magnificent planet. And the data we've taken from this system, I have no doubt will be used for decades to come, and I only hope we can go back one day.