A Nasa probe is to start photographing the icy world of Pluto, to prepare itself for a historic encounter in July.
The New Horizons spacecraft has travelled 5 billion km (3 billion miles) over nine years to get near the dwarf planet.
And with 200 million km (120 million miles) still to go, its images of Pluto will show only a speck of light against the stars.
But the data will be critical in helping to align the probe properly for what will be just a fleeting fly-by.
Pluto will be photographed repeatedly during the approach, to determine the probe’s position relative to the dwarf planet, explained Mark Holdridge, from the Johns Hopkins University’s Applied Physics Laboratory (JHUAPL) in Baltimore.
The Pluto system has five known moons. Others may be discovered in the coming months
Already, the SWAP, PEPSSI and SDC instruments are taking daily science data — measuring the charged particle and dust environment of the space near Pluto’s orbit. Next week, on Jan. 25, the sensitive LORRI long focal length camera aboard New Horizons will begin imaging the Pluto system for navigation purposes. This will yield dozens of images that our navigation teams will analyze for positional information about Pluto and Charon against star fields, allowing us to home in more accurately than by radio navigation from Earth alone.
Pluto’s atmosphere is composed primarily of nitrogen, just like Earth’s atmosphere. But its minor gases aren’t oxygen and argon – as on Earth – they are carbon monoxide and methane; other gases may also be present. Pluto’s atmospheric pressure is about the same as that in the Earth’s mesosphere, about 30 to 50 miles above the ground. Its atmosphere is known to display a mild greenhouse effect, as well as winds and, very likely, some hazes. There may even be clouds.
We also know that Pluto’s atmosphere is rapidly escaping, much like the way the early Earth’s atmosphere escaped, in a process called hydrodynamic escape. This happens when molecules high in the atmosphere are hot enough to simply flow away, a little like a cup of water filled up from the bottom and brimming over the rim.
As for Charon: it’s been speculated that this world, Pluto’s largest moon may, have an atmosphere. Perhaps it was captured (siphoned) off Pluto or created by internal activity or a recent cometary impact. But whatever (if anything) is there, it’s been too thin to find from Earth. New Horizons will attempt to do better.
Our objectives for atmospheric science during the flyby match the recommendations from the scientific advisory committees that worked with NASA to conceive a Pluto flyby mission; they include:
* Determine how Pluto’s atmospheric pressure and temperature vary from the surface to high altitude.
* Determine the atmosphere’s complete composition.
* Measure the atmospheric escape rate.
* Determine if Pluto has an ionosphere.
* Determine how Pluto’s atmosphere varies from place to place, and with seasons and time of day.
* Search for an atmosphere at Charon.
The closest approach to Pluto is set for around 11:50 GMT on 14 July – at a miss distance of roughly 13,695km from the surface.
Mission planners want the exact timings nailed to within 100 seconds. New Horizons will know then where and when to point the instruments.
Here’s a brief preview of the atmospheric science we’re planning for later this year, organized by instrument:
REX is our radio science experiment. On closest-approach day — July 14 — REX will intercept a set of four 20-kilowatt beams of radio energy sent to Pluto by giant 70-meter-wide antennas in NASA’s Deep Space Network. By measuring how these radio beams refract (or bend) through Pluto’s atmosphere, REX can help us determine the base pressure and temperature of Pluto’s atmosphere, as well as how those quantities vary with altitude above Pluto’s surface. REX can also determine another atmospheric quantity: the density of ionospheric layers high over Pluto.
Alice is our ultraviolet spectrometer. Many of the gases in Pluto’s atmosphere reveal themselves best at ultraviolet wavelengths. We’ll be using Alice over several weeks as we approach Pluto to search for emissions that reveal certain atomic gases like hydrogen, oxygen, nitrogen and argon in Pluto’s upper atmosphere. Then, on encounter day, we’ll fly into Pluto’s shadow and watch the Sun rise and set with Alice to determine the composition of the atoms and molecules in Pluto’s atmosphere as a function of height over the surface. We’ll also perform the same experiment at Charon to determine of it has a thin atmosphere and what that envelope may be made of. (REX will try to do the same, but it’s not as sensitive as Alice for detecting atmospheres as thin as Charon’s is likely to be.)
PEPSSI, which stands for Pluto Energetic Particle Spectrometer Science Investigation, measures high-energy ions that originate in Pluto’s atmosphere and accelerate as they stream away in the solar wind. PEPSSI will determine the composition as well as the densities of these ions; this will help us pin down Pluto’s atmospheric composition and escape rate.
SWAP, for Solar Wind Around Pluto, performs a clever measurement of Pluto’s total atmospheric escape rate. How? At some distance from Pluto, the atmospheric escape pressure balances with the incoming solar wind pressure – and the distance at which this occurs from Pluto reveals the rate of Pluto’s atmospheric escape. SWAP’s job is to accurately measure that distance by determining where the solar wind cuts off and Pluto’s atmosphere begins.
LORRI (our Long Range Reconnaissance Imager) and Ralph are primarily surface imagers – not atmospheric instruments – but they can shed light on Pluto’s atmosphere by searching for clouds and hazes, both as New Horizons approaches and recedes. In fact, LORRI and Ralph could, in principle, make the first atmospheric detections of Pluto by New Horizons by capturing images of just such phenomena, perhaps even weeks before REX, Alice, PEPSSI and SWAP conduct their investigations.
As you can see, we have a wide variety of ways to plumb Pluto’s atmosphere and search for one around Charon. The fun begins in May, and intensifies across June and July.
SOURCES – Nasa, BBC News