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Photographing Pluto: This Is How New Horizons Works

8 minute read

On January 19, 2006, the New Horizons space craft launched from Cape Canaveral on a mission that would take it over three billion miles away to an unprecedented rendezvous with the dwarf planet Pluto.

Nearly a decade later, the first images from that fly-by will be sent back to Earth on Wednesday – they will be the best and closest images of Pluto ever taken.

TIME Multimedia Editor Mia Tramz interviews Jeff Moore, the Geology and Geophysics Investigation (GGI) Theme Team leader, about the cameras they used for this historic mission and what these new images of Pluto may mean for our understanding of the universe.

TIME LightBox: How many cameras are on the space craft?

Jeff Moore: There’s two cameras that more or less operate in visible light: a color camera which is a medium resolution camera (Ralph), and then there’s a grayscale or black and white telephoto camera (Long Range Reconnaissance Imager, or LORRI).

Our long range pictures of things that are going to give us our highest resolution images will be taken LORRI. And the color pictures will be taken with Ralph. We can actually combine the colors from Ralph to colorize LORRI’s pictures.

And then there is an imaging infrared spectrometer that will also makes pictures of a sort. But they’re mostly compositional information, like what Pluto and its moons are made out of.

TIME LightBox: Was any new technology incorporated into the cameras?

Jeff Moore: At a relatively small level yes, but mainly the cameras represent mature technology of 15 years ago. If you’re going to launch a space craft that’s going to fly over three billion miles away from the Earth – and it’s going to take ten years to get there – you want to make sure that what you’re sending there is completely reliable.

So we did not use the latest most cutting edge technology, we used technology which we would be sure to work when we got there. We used cameras not too different from what you can buy at a camera store or in the back of your telephone. We made the cameras very robust and mechanically simple so that nothing could break and nothing could fail.

TIME LightBox: How long does it take to get an image back from the space craft?

Jeff Moore: In order to keep the mission economical so that NASA would have the resources to pay for [it], we did a few things such as using a relatively small radio antenna on the space craft. And we also bolted everything onto the space craft without any moving parts.

That means several things. When the space craft collects data, it usually does not have its antenna pointed at the Earth – the space craft has to reorient itself back to Earth to transmit data.

Also, at the distance of Pluto, we can only send data back at a rate that’s comparable with an old 1990s modem. Because of that, during the encounter, we’ll be taking many, many pictures, but those pictures will all be stored on the solid state memory and radioed back to the Earth months after the encounter.

Much of our best and most interesting data isn’t going to be seen until this fall or early next year. Of course we’re going to send back some very interesting high priority data during the days of the encounter itself.

TIME LightBox: How often are you receiving pictures from the space craft currently?

Jeff Moore: We are getting pictures back on a daily to weekly basis right now.

MORE: See The Trailer For TIME’s Unprecedented New Series: A Year In Space

TIME LightBox: Can you describe the different teams that will be working with these pictures and what data they’ll be looking for in the images?

Jeff Moore: There’s four teams: There is a Composition (COMP) Theme Team which will look mostly at the data from the infrared mapping spectrometer I described earlier. It doesn’t have the same pixel resolution as the cameras, but it takes pictures in over two hundred and fifty colors in the near infrared. They can make spectra of individual points on Pluto and determine what kinds of materials make up the surface of the planet.

Then there’s an Atmospheres (ATM) Theme Team. They will examine the structure and density and surface pressure and chemistry and winds of Pluto’s atmosphere.

And then last but not least there is a Particles and Plasma (P&P) Theme Team which will study the interaction of solar wind with the gases which come off of Pluto’s atmosphere and off its moons. They can tell a lot about the evolution and long term survivability of, or changes at least, in Pluto’s atmospheric history by looking at how these fields and particles from the Sun interact with the material and the vicinity of Pluto.

TIME LightBox: From your own personal point of view, what sorts of things are you most excited to start finding out about once the pictures come back from the fly-by?

Jeff Moore: The thing that I’m going to be most excited about is understanding the various geological processes that have operated to shape the surface. We see evidence that there’s been vast erosion and buildup of ices as Pluto goes through its extreme seasons.

Pluto has extreme seasons which may well drive very exotic land forms. We may see big landscapes that are eroded that look like Monument Valley and maybe other places which look like polar ice sheets.

It’s perfectly possible to see where the ground’s been broken and split into mountains or ridges or canyons from tectonic forces. We might even see evidence for an exotic form of volcanism where you have this very cold but volatile material that makes up Pluto. It might be warmed by radioactive minerals in the interior. There might be eruptions of ice or methane or nitrogen volcanoes. That can’t be ruled out.

And we expect to see probably at least a few impact craters here and there. If the surface has very few impact craters that means it’s very young. And Pluto has, up until recent times, or in recent times been geologically active. If it has lots of impact craters it means that most of the things that happened in the history of Pluto happened a long time ago.

There’s a lot of things we don’t know anything about. And figuring out how all these different geological processes worked in concert with each other and which came first will tell us the history of Pluto.

But I always tell everybody right now, what I really anticipate most about Pluto is to be surprised.

TIME LightBox: How do you anticipate this mission will contribute to our understanding of our universe?

Jeff Moore: Pluto may be the star witness to the whole third zone of the solar system. The inner zone of the solar system has the rocky planets like the Earth and Mars and so on. And the middle solar system have all the gas giants like Jupiter, Saturn, Uranus, Neptune and all their moons.

But then beyond those worlds, there is a vast realm of ice worlds which planets like Pluto represents the largest members of this third zone of the solar system, where water ice is considered to be something that never melts – it’s considered to be hard as rock, as un-meltable as rock.

The things that are operating on the surface at those temperatures instead are things like frozen nitrogen and frozen methane, which of course are gases on the Earth.

The things which make our atmosphere, or the stuff that comes out of our gas heated stoves, are the things which make up the surface materials and the rocks on these worlds like Pluto. And how they interact, it’s really not something we’ve seen a lot of or have any understanding of.

It represents in some sense one of the major regions of our solar system. Pluto may represent one of the more common types of worlds in the universe. And we simply haven’t seen such worlds before, so it’s going to be really exciting to see such a landscape for the first time.

This interview has been edited for length and clarity

Jeff Moore is the Geology and Geophysics Investigation (GGI) Theme Team leader for New Horizons. Follow the New Horizons Mission @NASANewHorizons.

Mia Tramz is a Multimedia Editor for TIME.com. Follow her on Twitter @miatramz.

New Horizons Jupiter Io
A montage of New Horizons' images of Jupiter and its volcanic moon Io, taken during the spacecraft's Jupiter flyby in early 2007. NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute
New Horizons Io Europa
A montage of New Horizons' images of the crescents of Io and Europa taken March 2, 2007, about two days after New Horizons made its closest approach to Jupiter. NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute
New Horizons Europa Jupiter
The icy moon Europa rising above Jupiter's cloud tops taken on Feb. 28, 2007, six hours after the spacecraft's closest approach to Jupiter.NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute
Jupiter's Moons: Family PortraitRelease Date: May 1, 2007Keywords: Callisto, crater, Europa, Galilean satellite, Ganymede, Io, Jupiter, LORRI, moon(s)This montage shows the best views of Jupiter's four large and diverse "Galilean" satellites as seen by the Long Range Reconnaissance Imager (LORRI) on the New Horizons spacecraft during its flyby of Jupiter in late February 2007. The four moons are, from left to right: Io, Europa, Ganymede and Callisto. The images have been scaled to represent the true relative sizes of the four moons and are arranged in their order from Jupiter.Io, 3,640 kilometers (2,260 miles) in diameter, was imaged at 03:50 Universal Time on February 28 from a range of 2.7 million kilometers (1.7 million miles). The original image scale was 13 kilometers per pixel, and the image is centered at Io coordinates 6 degrees south, 22 degrees west. Io is notable for its active volcanism, which New Horizons has studied extensively. Europa, 3,120 kilometers (1,938 miles) in diameter, was imaged at 01:28 Universal Time on February 28 from a range of 3 million kilometers (1.8 million miles). The original image scale was 15 kilometers per pixel, and the image is centered at Europa coordinates 6 degrees south, 347 degrees west. Europa's smooth, icy surface likely conceals an ocean of liquid water. New Horizons obtained data on Europa�s surface composition and imaged subtle surface features, and analysis of these data may provide new information about the ocean and the icy shell that covers it.New Horizons spied Ganymede, 5,262 kilometers (3,268 miles) in diameter, at 10:01 Universal Time on February 27 from 3.5 million kilometers (2.2 million miles) away. The original scale was 17 kilometers per pixel, and the image is centered at Ganymede coordinates 6 degrees south, 38 degrees west. Ganymede, the largest moon in the solar system, has a dirty ice surface cut by fractures and peppered by impact craters. New Horizons� infrared observations may prov
A montage of the best views of Jupiter's four "Galilean" satellites as seen by the Long Range Reconnaissance Imager (LORRI) on the New Horizons spacecraft during its flyby of Jupiter in late Feb. 2007. The four moons are, from left to right: Io, Europa, Ganymede and Callisto. The images have been scaled to represent the true relative sizes of the four moons and are arranged in their order from Jupiter.NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute
New Horizons Jupiter Io Ganymede
The New Horizons LORRI took this 2-millisecond exposure of Jupiter on Jan. 24, 2007. The spacecraft was 57 million kilometers (35.3 million miles) from Jupiter, closing in on the giant planet at 41,500 miles (66,790 kilometers) per hour. At right are the moons Io (bottom) and Ganymede; Ganymede's shadow creeps toward the top of Jupiter's northern hemisphere. NASA/Johns Hopkins University Applied Physics Laboratory/Southwest Research Institute
Pluto and Charon display striking color and brightness contrast in this composite image from July 11.
Pluto and Charon display striking color and brightness contrast in this composite image from July 11. NASA-JHUAPL-SWRI
Pluto nearly fills the frame in this image from the Long Range Reconnaissance Imager (LORRI) aboard NASA’s New Horizons spacecraft, taken on July 13, 2015, when the spacecraft was 476,000 miles (768,000 kilometers) from the surface. This is the last and most detailed image sent to Earth before the spacecraft’s closest approach to Pluto on July 14.
Pluto nearly fills the frame in this image from the Long Range Reconnaissance Imager (LORRI) aboard NASA’s New Horizons spacecraft, taken on July 13, 2015, when the spacecraft was 476,000 miles (768,000 kilometers) from the surface. This is the last and most detailed image sent to Earth before the spacecraft’s closest approach to Pluto on July 14.NASA/APL/SwRI

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Write to Mia Tramz at mia.tramz@time.com