Rosetta (spacecraft)

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Rosetta

Organization	European Space Agency
Major contractors	European Space Agency
Mission type	Comet Orbiter/Lander
Flyby of	Earth, Mars, 2867 Šteins, 21 Lutetia
Satellite of	67P/Churyumov-Gerasimenko
Launch date	March 2, 2004 at 07:17 UTC
Launch vehicle	Ariane 5
Decay	N/A
Webpage	ESA-Rosetta

Rosetta is a European Space Agency-led robotic spacecraft mission launched in 2004 intended to study the comet 67P/Churyumov-Gerasimenko. Rosetta consists of two main elements: the Rosetta space probe and the Philae lander. The probe is named after the Rosetta Stone, as it is hoped the mission will help unlock the secrets of how our solar system looked before planets formed. The lander is named after the Nile island Philae where an obelisk was found that helped decipher the Rosetta Stone.

1 Overview
2 Mission timeline
3 Instruments
4 Major events and discoveries
5 References
6 External links

Overview

During the 1986 apparition of the Comet Halley, a number of international space probes were sent to explore the cometary system, most prominent among them being ESA's highly successful Giotto. After the probes returned a treasure-trove of valuable scientific information it was becoming obvious that follow-ons were needed that would shed more light on the complex cometary composition and resolve the newly opened questions.

Both NASA and ESA started cooperatively developing new probes, the NASA led effort was the Comet Rendezvous Asteroid Flyby or CRAF mission, the follow-on Comet Nucleus Sample Return or CNSR mission was to be an ESA led effort, both missions were to share the common Mariner Mark II design, thus minimizing costs. In 1992, after NASA axed CRAF because of budgetary limitations, ESA decided on developing the spacecraft by themselves. By 1993 it was evident that the ambitious sample return mission was unfeasible with the existing ESA budget, so instead the mission was redesigned, with the final flight plan resembling the canceled CRAF mission, an asteroid flyby followed by a comet rendezvous with in-situ examination, including a lander.

Rosetta was built in a clean room according to COSPAR rules, but "Sterilisation [was] generally not crucial since comets are usually regarded as objects where you can find prebiotic molecules, that is, molecules that are precursors of life, but not living microorganisms,"^[1] according to Gerhard Schwehm, Rosetta's Project Scientist.

It was set to be launched on January 12, 2003 to rendezvous with the comet 46P/Wirtanen in 2011.

Trajectory of the Rosetta Space Probe

However this plan was abandoned after an Ariane 5 failure on December 11, 2002. A new plan was formed to target the comet 67P/Churyumov-Gerasimenko with launch on February 26, 2004 and rendezvous in 2014. The larger mass and the resulting increased impact velocity made modification of the landing gear necessary.^[2] After two cancelled launch attempts, Rosetta was launched on March 2, 2004 at 7:17 GMT. Besides the changes made to launch time and target, the mission profile remains almost identical.

On 25 February 2007, the Rosetta craft was scheduled for a low-altitude bypass of Mars, as this was needed to correct the trajectory after the first lauch in 2003 was delayed by one year. This was not without risk, as the estimated altitude of the flyover manoeuvre was a mere 250 km (155 miles). Furthermore, the solar panels could not be used as the craft was at the far side of Mars, where it would not receive any solar light for 15 minutes, causing a dangerous shortage of power. The craft was therefore put into standby mode, with no possibility to communicate, flying on batteries that were originally not designed for this task.^[3] This Mars manouvre was therefore nicknamed "The Billion Dollar Gamble".^[4] Fortunately, the flyby was successful at 03:15 CET and the mission now continues.^[5]

The second Earth flyby took place on November 13, 2007.^[6]^[7]

In May 2014, the Rosetta craft will enter a very slow orbit around the comet and gradually slow down in preparation for releasing a lander that will make contact with the comet itself. The lander, named "Philae", will approach 67P/Churyumov-Gerasimenko at relative speed around 1 m/s and on contact with the surface, two harpoons will be fired into the comet to prevent the lander from bouncing off. Additional drills are used to further secure the lander on the comet.

Once attached to the comet, expected to take place in November 2014, the lander will begin its science mission:

Characterisation of the nucleus
Determination of the chemical compounds present
Study of comet activities and developments over time

The exact surface layout of the comet is currently unknown and the orbiter has been built to map this before detaching the lander. It is anticipated that a suitable landing site can be found, although few specific details exist regarding the surface.

Mission timeline

Main article: Rosetta space probe timeline

Computer model of Rosetta probe

This is the planned timeline for the mission after its launch:
- First Earth flyby (March 2005)
- February 25 2007 Mars flyby
- November 13 2007 Second Earth flyby
- September 5 2008 - flyby of asteroid 2867 Šteins
- Third Earth flyby (November 2009)
- July 10 2010 - flyby of asteroid 21 Lutetia
- Deep-space hibernation (May 2011 - January 2014)
- Comet approach (January-May 2014)
- Comet mapping / Characterisation (August 2014)
- Landing on the comet (November 2014)
- Escorting the comet around the Sun (November 2014 - December 2015)

Ariane 5 Launch of Rosetta spacecraft

Instruments

Core

The spectroscopical investigation of the core is done by four instruments:

ALICE (An Ultraviolet Imaging Spectrometer). The UV spectrometer should search for the abundance of noble gas in the comet core, from which the temperature during the comet creation could be estimated. The detection is done by an array of potassium bromide and caesium iodide photocathodes. The 3.1 kg instrument uses 2.9 Watt and was produced in the USA, and an improved version is used in the New Horizons.^[8]^[9]

OSIRIS (Optical, Spectroscopic, and Infrared Remote Imaging System). The camera system consisting of a narrow angle (700 mm) and a wide angle camera (140 mm), with an 2048x2048 pixel CCD chip each will take pictures of the comets. The instrument was constructed in Germany.^[10]

VIRTIS (Visible and Infrared Thermal Imaging Spectrometer). The Visible and IR spectrometer is able to make pictures of the core in the IR and also search for IR spectra of molecules in the coma. The detection is done by a mercury cadmium teluride array for IR and with a CCD chip for the Visible range. The instrument was produced in Italy, and improved versions were used for Dawn and Venus express.^[11]

MICRO (Microwave Instrument for the Rosetta Orbiter). With the microwave emissions the temperature and the abundance of volatile substances (like water, ammonia and carbon dioxide) can be detected. The 30 cm Radio antenna was constructed in Germany, while the rest of the 18.5 kg instrument was provided by the USA.

The radar tomography of the nucleus is done by:

CONSERT (Comet Nucleus Sounding Experiment by Radiowave Transmission). The CONSERT experiment is the only experiment on board the ROSETTA mission which will provide information about the deep interior of the comet. The Consert radar will perform the tomography of the nucleus by measuring electromagnetic wave propagation from the Philae lander and the Rosetta orbiter throughout the comet nucleus in order to determine its internal structures and to deduce information on its composition. The lander and orbiter electronics was provided by France and both antennas were constructed in Germany.^[12]

Gas and particles

ROSINA (Rosetta Orbiter Spectrometer for Ion and Neutral Analysis). The instrument consists a double focus magnetic mass spectrometer DFMS and a reflectron type time of flight mass spectrometer RTOF. The DFMS has a high resolution (can resolve N₂ from CO) for molecules up to 300amu. The RTOF is highly sensitive for neutral molecules and for ions.^[13]

MIDAS (Micro-Imaging Dust Analysis System). The high resolution atomic force microscope will investigate the dust particles which are deposited on a silicone plate.^[14]

COSIMA (Cometary Secondary Ion Mass Analyser).Composition of dust particles is analysed, after the surface is cleand by indium ions, by secondary ion mass spectrometry. Ions up to a mass of 4000 amu is possible.^[15]

Solarwind interaction

GIADA (Grain Impact Analyser and Dust Accumulator) ^[16]

RPC (Rosetta Plasma Consortium) ^[17]

Major events and discoveries

2004

March 2 - ESA's Rosetta mission is successfully launched at 07:17 GMT (08:17 Central European Time). The launcher successfully placed its upper stage and payload into an eccentric coast orbit (200 x 4000 km). About two hours later, at 09:14 GMT, the upper stage ignited its own engine to reach an escape velocity in order to leave the Earth’s gravity field and enter heliocentric orbit. The Rosetta probe was released 18 minutes later. ESA’s Operations Centre (ESOC) in Darmstadt, Germany, established contact with the probe shortly after that.

May 10 - The first and most important deep space maneuver was successfully executed and brings the space craft on its correct course, with a reported inaccuracy of 0.05%.

2005

March 4 - Rosetta executed its first planned close flyby of Earth. The Moon and the Earth's magnetic field were used to test and calibrate the instruments on board of the spacecraft. The minimum altitude above the Earth's surface was about 1954.7 km at 22:09 UTC and images of the space probe passing by were captured by amateur astronomers.^[18]

July 4 - Imaging instruments on board observed the collision between the comet Tempel 1 and the impactor of the Deep Impact mission.^[19]

2007

February 25 -- Mars swing-by. Philae's ROMAP (Rosetta Lander Magnetometer and Plasma Monitor) instrument measures the complex Martian magnetic environment,^[20] while Rosetta's OSIRIS (Optical, Spectroscopic, and Infrared Remote Imaging System) took various images of the planet using different photographic filters.^[21] While in Mars' shadow most of the instruments were turned off the Philae lander was autonomously running on batteries. During this operation the ÇIVA instrument on the lander took pictures of Mars.^[22]^[23] Among others, both actions were meant to test the spacecraft's instruments while the probe needed the gravity of Mars to change directions in order to undertake its second Earth flyby in November.^[24]

November 8 -- As Rosetta approached the Earth for its second flyby scheduled for November 13, it was observed by a 0.68 meter telescope of the Catalina Sky Survey near Tucson, Arizona as a moving object on survey images from November 7 and its positions were reported to the Minor Planet Center. After additional observations on November 8 the Minor Planet Center misidentified the spacecraft as a Near Earth Object on a course that would bring it within 0.89 earth radii from the surface of the Earth and gave it the provisional designation asteroid 2007 VN84. Following a suggestion on a news group, the misidentification was corrected and the asteroid designation was cancelled one hour and 16 minutes later.^[25]

References

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^ S.A. Stern, D.C. Slater, J. Scherrer, J. Stone, M. Versteeg, M.F. A'Hearn, J.L. Bertaux, P.D. Feldman, M.C. Festou, J.Wm. Parker, O.H.W. Siegmund. "Alice: The Rosetta Ultraviolet Imaging Spectrograph". Astrophysics, abstract.
^ S.A. Stern, D.C. Slater, J. Scherrer, M.F. A'Hearn, J.L. Bertaux, P.D. Feldman, M.C. Festou, O.H.W. Siegmund. "Alice: The Rosetta Ultraviolet Imaging Spectrograph".
^ Thomas., N.; Keller, H. U.; Arijs, E.; Barbieri, C.; Grande, M.; Lamy, P.; Rickman, H.; Rodrigo, R.; Wenzel, K.-P.; A'Hearn, M. F.; Angrilli, F.; Bailey, M.; Barucci, M. A.; Bertaux, J.-L.; Brieß, K.; Burns, J. A.; Cremonese, G.; Curdt, W.; Deceuninck, H.; Emery, R.; Festou, M.; Fulle, M.; Ip, W.-H.; Jorda, L.; Korth, A.; Koschny, D.; Kramm, J.-R.; Kührt, E.; Lara, L. M.; Llebaria, A.; Lopez-Moreno, J. J.; Marzari, F.; Moreau, D.; Muller, C.; Murray, C.; Naletto, G.; Nevejans, D.; Ragazzoni, R.; Sabau, L.; Sanz, A.; Sivan, J.-P.; Tondello, G.. "OSIRIS-the optical, spectroscopic and infrared remote imaging system for the Rosetta Orbiter". Advances in Space Research 21: 1505-1515. doi:10.1016/S0273-1177(97)00943-5.
^ Coradini, A.; Capaccioni, F.; Capria, M. T.; Cerroni, P.; de Sanctis, M. C.; Magni, G.; Reininger, F.; Drossart, P.; Barucci, M. A.; Bockelee-Morvan, D.; Combes, M.; Crovisier, J.; Encrenaz, T.; Tiphene, D.; Arnold, G.; Carsenty, U.; Michaelis, H.; Mottola, S.; Neukum, G.; Schade, U.; Taylor, F.; Calcutt, S.; Vellacott, T.; Venters, P.; Watkins, R. E.; Bellucci, G.; Formisano, V.; Angrilli, F.; Bianchini, G.; Saggin, B.; Bussoletti, E.; Colangeli, L.; Mennella, V.; Fonti, S.; Tozzi, G.; Bibring, J. P.; Langevin, Y.; Schmitt, B.; Combi, M.; Fink, U.; McCord, T.; Ip, W.; Carlson, R. W.; Jennings, D. E.. "VIRTIS Visible Infrared Thermal Imaging Spectrometer for Rosetta Mission". Lunar and Planetary Science 27: 253.
^ Kofman, W., A. Herique, J-P. Goutail, T. Hagfors, I. P. Williams, E. Nielsen, J-P. Barriot, Y. Barbin, C.Elachi, P. Edenhofer, A-C. Levasseur-Regourd, D. Plettemeier, G . Picardi, R.Seu, V. Svedhem (2007). "The Comet Nucleus Sounding Experiment by Radiowave Transmission (CONSERT). A short description of the instrument and of the commissioning stages". Space Science Reviews 128: 413-432. doi:10.1007/s11214-006-9034-9.
^ Balsiger H, Altwegg K, Arijs E, Bertaux JL, Berthelier JJ, Bochsler P, Carignan GR, Eberhardt P, Fisk LA, Fuselier SA, Ghielmetti AG, Gliem F, Gombosi TI, Kopp E, Korth A, Livi S, Mazelle C, Reme H, Sauvaud JA, Shelley EG, Waite JH, Wilken B, Woch J, Wollnik H, Wurz P, Young DT (1998). "Rosetta Orbiter Spectrometer for ion and neutral analysis-ROSINA". Advances in Space Research 21: 1527-1535. doi:10.1016/S0273-1177(97)00945-9. }
^ BRiedler W, Torkar K, Rudenauer F, Fehringer M, Schmidt R, Arends H, Grard RJL, Jessberger EK, Kassing R, Alleyne HS, Ehrenfreund P, Levasseur-Regourd AC, Koeberl C, Havnes O, Klock W, Zinner E, Rott M (1998). "The MIDAS experiment for the Rosetta mission". Advances in Space Research 21: 1547-1556. doi:10.1016/S0273-1177(97)00947-2. }
^ C. Engrand, J. Kissel, F. R. Krueger, P. Martin, J. Silén, L. Thirkell, R. Thomas, K. Varmuza. "Chemometric evaluation of time-of-flight secondary ion mass spectrometry data of minerals in the frame of future in situ analyses of cometary material by COSIMA onboard ROSETTA". Rapid Communications in Mass Spectrometry 20: 1361-1368. doi:10.1002/rcm.2448.
^ Bussoletti, E.; Colangeli, L.; Lopez Moreno, J. J.; Epifani, E.; Mennella, V.; Palomba, E.; Palumbo, P.; Rotundi, A.; Vergara, S.; Girela, F.; Herranz, M.; Jeronimo, J. M.; Lopez-Jimenez, A. C.; Molina, A.; Moreno, F.; Olivares, I.; Rodrigo, R.; Rodriguez-Gomez, J. F.; Sanchez, J.; Mc Donnell, J. A. M.; Leese, M.; Lamy, P.; Perruchot, S.; Crifo, J. F.; Fulle, M.; Perrin, J. M.; Angrilli, F.; Benini, E.; Casini, L.; Cherubini, G.; Coradini, A.; Giovane, F.; Grün, E.; Gustafson, B.; Maag, C.; Weissmann, P. R.. "The GIADA Experiment for Rosetta Mission to Comet 46P/Wirtanen: Design and Performances". Advances in Space Research 24: 1139-1148. doi:10.1016/S0273-1177(99)80207-5.
^ Trotignon JG, Bostrom R, Burch JL, Glassmeier KH, Lundin R, Norberg O, Balogh A, Szego K, Musmann G, Coates A, Ahlen L, Carr C, Eriksson A, Gibson W, Kuhnke F, Lundin K, Michau JL, Szalai S. "The ROSETTA Plasma Consortium: Technical realization and scientific aims". Advances in Space Research 24: 1149-1158. doi:10.1016/S0273-1177(99)80208-7.
^ E. Montagnon, P. Ferri (2006). "Rosetta on its way to the outer solar system". Acta Astronautica 59: 301-309.
^ http://www.esa.int/esaCP/SEMSJ06DIAE_index_0.html
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