Science

Huygens begins its final journey into the unknown

Huygens begins its final journey into the unknown
The Huygens Probe will enter the upper layers of Titan's atmosphere at 22000 km/h, slowing to about 1400 km/h in less than 2 minutes. Artists view courtesy of ESA-D. DUCROS
The Huygens Probe will enter the upper layers of Titan's atmosphere at 22000 km/h, slowing to about 1400 km/h in less than 2 minutes. Artists view courtesy of ESA-D. DUCROS
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Eminent Dutch scientist Christiaan Huygens (1629-1695) discovered Titan in 1655, and was the first to deduce that Saturn was surrounded by a ring. He also invented the pendulum clock, the first accurate time-keeping device. Painting by Vaillant, courtesy
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Eminent Dutch scientist Christiaan Huygens (1629-1695) discovered Titan in 1655, and was the first to deduce that Saturn was surrounded by a ring. He also invented the pendulum clock, the first accurate time-keeping device. Painting by Vaillant, courtesy
It is not possible to launch a spacecraft as massive as Cassini/Huygens with sufficient energy to reach Saturn directly, so it gains energy en route by flying close to other planets to receive assists from their gravitational fields. Image ESA
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It is not possible to launch a spacecraft as massive as Cassini/Huygens with sufficient energy to reach Saturn directly, so it gains energy en route by flying close to other planets to receive assists from their gravitational fields. Image ESA
When Cassini reaches Saturn, a long burn of its engines will slow it so it is captured by the planet's gravitational field into an elliptical orbit. At the extreme point of this initial orbit, a manoeuvre will direct it to pass close to Titan Image: ESA
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When Cassini reaches Saturn, a long burn of its engines will slow it so it is captured by the planet's gravitational field into an elliptical orbit. At the extreme point of this initial orbit, a manoeuvre will direct it to pass close to Titan Image: ESA
Artist's impression of Huygens descending through Titan's atmosphere. Image: ESA
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Artist's impression of Huygens descending through Titan's atmosphere. Image: ESA
This is an artist's impression of the Cassini-Huygens spacecraft approaching Saturn and its magnificent rings. The glint of light behind the magnetometer boom at the bottom of the spacecraft is a reflection of the Sun. Image: NASA
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This is an artist's impression of the Cassini-Huygens spacecraft approaching Saturn and its magnificent rings. The glint of light behind the magnetometer boom at the bottom of the spacecraft is a reflection of the Sun. Image: NASA
On the upper surface can be seen the two redundant antennas (black) that will transmit scientific data back to the Cassini orbiter travelling past Titan at almost 6 km/s at a distance of 75000 - 25000 km during the 2-2 1/2 hr of the descent. Pic - ESA
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On the upper surface can be seen the two redundant antennas (black) that will transmit scientific data back to the Cassini orbiter travelling past Titan at almost 6 km/s at a distance of 75000 - 25000 km during the 2-2 1/2 hr of the descent. Pic - ESA
Artist view of the Huygens Probe approaching the upper layers of Titan's atmosphere at 22000 km/h Image: NASA/ESA
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Artist view of the Huygens Probe approaching the upper layers of Titan's atmosphere at 22000 km/h Image: NASA/ESA
The Huygens Probe is integrated with the Saturn orbiter in the Payload Hazardous Servicing Facility at NASA's Kennedy Space Center in Florida. Picture: ESA/NASA
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The Huygens Probe is integrated with the Saturn orbiter in the Payload Hazardous Servicing Facility at NASA's Kennedy Space Center in Florida. Picture: ESA/NASA
An artist's impression of the separation Image: ESA-D. DUCROS
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An artist's impression of the separation Image: ESA-D. DUCROS
Titan's complex surface. Photo: NASA/JPL/University of Arizona
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Titan's complex surface. Photo: NASA/JPL/University of Arizona
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The narrow-angle camera on board the Cassini-Huygens spacecraft took a series of exposures of Saturn and its rings and moons on 9 February 2004, which were composited to create this stunning, colour image. At the time, Cassini was 69.4 million kilometres
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The narrow-angle camera on board the Cassini-Huygens spacecraft took a series of exposures of Saturn and its rings and moons on 9 February 2004, which were composited to create this stunning, colour image. At the time, Cassini was 69.4 million kilometres
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This image shows Saturn, its ring structure and satellites to relative scale unless otherwise noted. Illustration by David Seal Image courtesy of NASA/JPL/Caltech
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This image shows Saturn, its ring structure and satellites to relative scale unless otherwise noted. Illustration by David Seal Image courtesy of NASA/JPL/Caltech
The Huygens Probe will enter the upper layers of Titan's atmosphere at 22000 km/h, slowing to about 1400 km/h in less than 2 minutes. Artists view courtesy of ESA-D. DUCROS
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The Huygens Probe will enter the upper layers of Titan's atmosphere at 22000 km/h, slowing to about 1400 km/h in less than 2 minutes. Artists view courtesy of ESA-D. DUCROS
View gallery - 15 images

3 January 2005 Global cooperation will see yet another frontier breached in the next week as the European Space Agency's Huygens probe makes its descent towards the surface of Saturn's largest and most mysterious moon, Titan. The European Space Agency's Huygens probe was successfully released by NASA's Cassini orbiter on Christmas Day and is now on a controlled collision course toward Titan, where on 14 January it will make a descent through one of the most intriguing atmospheres in the solar system to an unknown surface. This will be the first man-made object to explore in-situ this unique environment, whose chemistry is assumed to be very similar to that of the early Earth just before life began, 3.8 billion years ago.

A few minutes after separation, Cassini turned back to Earth and relayed back information about the separation. This signal then took 1 hour and 8 minutes to cross the 1.2 billion kilometres separating the Cassini spacecraft and Earth. "Today's release is another successful milestone in the Cassini/Huygens odyssey", said Dr David Southwood, ESA's director of science programmes. "This was an amicable separation after seven years of living together. Our thanks to our partners at NASA for the lift. Each spacecraft will now continue on its own but we expect they'll keep in touch to complete this amazing mission. Now all our hopes and expectations are focused on getting the first in-situ data from a new world we've been dreaming of exploring for decades".

Final stage of a seven year odyssey

The Cassini/Huygens mission, jointly developed by NASA, ESA and the Italian space agency (ASI), began on 15 October 1997, when the composite spacecraft were launched from Cape Canaveral, Florida, atop a Titan 4B/Centaur vehicle.

Together, the two probes weighed 5548 kg at launch and became the largest space mission ever sent to the outer planets. To gain sufficient velocity to reach Saturn, they had to conduct four gravity-assist manoeuvres by flying twice by Venus, once by the Earth and once by Jupiter. On 1 July 2004, Cassini/Huygens eventually became the first spacecraft to enter an orbit around Saturn.

On 17 December, while on its third orbit around the ringed planet, the Cassini orbiter performed a manoeuvre to enter a controlled collision trajectory towards Titan.

A fine-tuning of the trajectory took place on 22 December to place Huygens on its nominal entry trajectory. While Huygens will remain on this trajectory till it plunges into Titan's atmosphere on 14 January, the orbiter performed a deflection manoeuvre on 28 December to avoid crashing onto the moon. The Christmas Day separation was achieved by the firing of pyrotechnic devices. Under the action of push-off springs, ramps and rollers, the probe was released at a relative velocity of about 0.3 m/s with a spin rate of 7 rpm.

Telemetry data confirming the separation were collected by NASA's Deep Space Network stations in Madrid, Spain and Goldstone, California, when the telemetry playback signal from Cassini eventually reached the Earth.

The Huygens probe is now dormant and will remain so throughout its 20-day coast phase to Titan. Four days before its release, a triply-redundant timer was programmed in order to wake-up the probe's systems shortly before arrival on Titan.

Exploring Titan's atmosphere

Huygens is scheduled to enter Titan's atmosphere at about 09:06 UTC (10:06 CET) on 14 January, entering at a relatively steep angle of 65° and a velocity of about 6 km/s. The target is over the southern hemisphere, on the day side.

Protected by an ablative thermal shield, the probe will decelerate to 400 m/s within 3 minutes before it deploys a 2.6 m pilot chute at about 160 km. After 2.5 seconds this chute will pull away the probe's aft cover and the main parachute, 8.3 m in diameter, will deploy to stabilise the probe.

The front shield will then be released and the probe, whose main objective is to study Titan's atmosphere, will open inlet ports and deploy booms to collect the scientific data. All instruments will have direct access to the atmosphere to conduct detailed in-situ measurements of its structure, dynamics and chemistry. Imagery of the surface along the track will also be acquired. These data will be transmitted directly to the Cassini orbiter, which, at the same time, will be flying over Titan at 60 000 km at closest approach. Earth-based radiotelescopes will also try to detect the signal's tone directly.

After 15 minutes, at about 120 km, Huygens will release its main parachute and a smaller 3 m drogue chute will take over to allow a deeper plunge through the atmosphere within the lifetime of the probe's batteries.

The descent will last about 140 minutes before Huygens impacts the surface at about 6 m/s. If the probe survives all this, its extended mission will start, consisting in direct characterisation of Titan's surface for as long as the batteries can power the instruments and the Cassini orbiter is visible over the horizon at the landing site, i.e. not more than 130 minutes.

At that time, the Cassini orbiter will reorient its main antenna dish toward Earth in order to play back the data collected by Huygens, which will be received by NASA's 70-m diameter antenna in Canberra, Australia, 67 minutes later.

Three playbacks are planned, to ensure that all recorded data are safely transmitted to Earthl. Then Cassini will continue its mission exploring Saturn and its moons, which includes multiple additional flybys of Titan in the coming months and years. A probe deep into space and time

Bigger than Mercury and slightly smaller than Mars, Titan is unique in having a thick hazy nitrogen-rich atmosphere containing carbon-based compounds that could yield important clues about how Earth came to be habitable.

The chemical makeup of the atmosphere is thought to be very similar to Earth's before life began, although colder (-180°C) and so lacking liquid water. The in-situ results from Huygens, combined with global observations from repeated flybys of Titan by the Cassini orbiter, are thus expected to help us understand not only one of the most exotic members of our solar system but also the evolution of the early Earth's atmosphere and the mechanisms that led to the dawn of life on our planet.

Europe's main contribution to the Cassini mission, the Huygens probe was built for ESA by an industrial team led by Alcatel Space. This 320 kg spacecraft is carrying six science instruments to study the atmosphere during its descent. Laboratories and research centres from all ESA member countries, the United States, Poland and Israel have been involved in developing this science payload.

The Huygens atmospheric structure instrument package (HASI) will measure temperature and pressure profiles, and characterise winds and turbulences. It will also be able to detect lightning and even to measure the conductivity and permittivity of the surface if the probe survises the impact. The gas chromatograph mass spectrometer (GCMS) will provide fine chemical analysis of the atmosphere and the aerosols collected by the aerosol collector and pyrolyser (ACP). The descent imager/spectral radiometer (DISR) will collect images, spectra and other data on the atmosphere, the radiation budget, cloud structures, aerosols and the surface. The doppler wind experiment (DWE) will provide a zonal wind profile while the surface science package (SSP) will characterise the landing site if Huygens survives the impact.

The Cassini-Huygens mission is a cooperation between NASA, the European Space Agency and ASI, the Italian space agency. The Jet Propulsion Laboratory (JPL), a division of the California Institute of Technology in Pasadena, is managing the mission for NASA's Office of Space Science, Washington. JPL designed, developed and assembled the Cassini orbiter.

On 17 December the orbiter will be placed on a controlled collision course with Titan in order to release Huygens on the proper trajectory, and on 21 December (some dates and times are subject to minor adjustment for operational reasons, except the entry time on 14 January which is know to within an accuracy of under 2 minutes) all systems will be set up for separation and the Huygens timers will be set to wake the probe a few hours before its arrival at Titan.

Messages from earthlings and pop music heading to Titan

Before the mission was launched, ESA offered Europeans a unique opportunity to send a message to the unknown. Over 80 000 people wanted to share the excitement of this mission and wrote or drew a message that was engraved on a CD-ROM put on board the Huygens probe. The messages can be seen on http://television.esa.int/Huygens/index.cfm

The same CD ROM carries four pop songs, composed by French musicians Julien Civange and Louis Haéri. More about this project at http://www.music2titan.com

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