ExoMars Trace Gas Orbiter

ExoMars Trace Gas Orbiter

ExoMars Trace Gas Orbiter with Schiaparelli lander
Mission type Mars orbiter & lander
Operator ESA, RKA
Website exploration.esa.int/mars
Mission duration 7 years (planned)[1][2]
Spacecraft properties
Manufacturer Thales Alenia Space
OHB
Launch mass TGO: 3,732 kg (8,228 lb)[3]
EDM: 600 kg (1,300 lb)
Dry mass TGO: 1,432 kg (3,157 lb)
Payload mass TGO: 116 kg (256 lb)
EDM: 5 kg (11 lb)
Power ~2000 W
Start of mission
Launch date March 14, 2016 (2016-03-14)[4]
Rocket Proton-M/Briz-M
Launch site Baikonur 200/39
Contractor ILS
Orbital parameters
Reference system Areocentric
Regime Circular
Eccentricity 0
Periareion 400 km (250 mi)
Apoareion 400 km (250 mi)
Inclination 74 degrees
Period 120 minutes
Epoch planned
Mars orbiter
Spacecraft component TGO
Orbital insertion October 19, 2016 (2016-10-19)
Mars lander
Spacecraft component EDM
Landing date October 19, 2016 (2016-10-19)
Landing site Meridiani Planum
Main telescope
Name CaSSIS
Type Three-mirror anastigmat
Diameter 13.5 cm (5.3 in)
Focal length 88 cm (35 in)
Wavelengths from 0.475 µm (blue)
to 0.95 µm (near-infrared)
Instruments
NOMAD Nadir and Occultation for MArs Discovery
ACS Atmospheric Chemistry Suite
CaSSIS Colour and Stereo Surface Imaging System
FREND Fine Resolution Epithermal Neutron Detector
ExoMars
ExoMars rover

The ExoMars Trace Gas Orbiter (TGO) is a collaborative project between the European Space Agency (ESA) and the Russian Federal Space Agency (Roscosmos) to send an atmosphere research orbiter and the Schiaparelli demonstration lander to Mars in 2016 as part of the European-led ExoMars mission.[5][6] The mission will follow with the ExoMars rover in 2020,[7] in which the 2016 launched TGO spacecraft will also operate as a communication link with Earth and the rover.

The Trace Gas Orbiter will deliver the ExoMars Schiaparelli EDM lander and then proceed with atmospheric mapping. A key goal of this mission is to gain a better understanding of methane and other atmospheric gases present in the Martian atmosphere that could be evidence for possible biological or geological activity. This research will also help select the landing site for the 2020 ExoMars rover which will search for biomolecules and biosignatures.

History

Investigations with space and Earth-based observatories have demonstrated the presence of small amounts of methane on the atmosphere of Mars that seems to vary with location and time.[8][9][10] This may indicate the presence of microbial life on Mars, or a geochemical process such as volcanism or hydrothermal activity.[11][12][13][14]

The challenge to discern the source of methane in the atmosphere of Mars prompted the independent planning by ESA and NASA of one orbiter each that would carry instruments in order to determine if its formation is of biological or geological origin,[15][16] as well as its decomposition products such as formaldehyde and methanol.

Attempted collaboration with NASA

NASA's Mars Science Orbiter (MSO) was originally envisioned in 2008 as an all NASA endeavor aiming for a late 2013 launch.[17][18] NASA and ESA officials agreed to pool resources and technical expertise and collaborate to launch only one orbiter.[19] The agreement, called Mars Joint Exploration Initiative, was signed on July 2009 and proposed to utilize an Atlas rocket launcher instead of a Soyuz rocket, which significantly altered the technical and financial setting of the European ExoMars mission. Since the ExoMars rover was originally planned to be launched along the TGO, a prospective agreement would require that the rover lose enough weight to fit aboard the Atlas launch vehicle with NASA's orbiter.[20] Instead of reducing the rover's mass, it was nearly doubled when the mission was combined with other projects to a multi-spacecraft programme divided over two Atlas V-launches:[19][21][22] the ExoMars Trace Gas Orbiter (TGO) was merged into the project, carrying a meteorological lander slated for launch in 2016. The European orbiter would carry several instruments originally meant for NASA's MSO, so NASA scaled down the objectives and focused on atmospheric trace gases detection instruments for their incorporation in ESA's ExoMars Trace Gas Orbiter.[6][18][23]

Under the FY2013 budget President Obama released on February 13, 2012, NASA terminated its participation in ExoMars due to budgetary cuts in order to pay for the cost overruns of the James Webb Space Telescope.[24][25] With NASA's funding for this project cancelled, most of ExoMars' plans had to be restructured.[26]

Collaboration with Russia

On March 15, 2012, the ESA's ruling council announced it will press ahead with its ExoMars program in partnership with the Russian space agency (Roscosmos), which plans to contribute two heavy-lift Proton launch vehicles and an additional entry, descent and landing system to the 2020 rover mission.[27][28][29][30][31]

Status

Under the collaboration proposal with Roscosmos, the ExoMars mission is split into two parts: the orbiter/lander mission in March 2016 that includes the TGO and a static lander build by ESA named Schiaparelli; this will be followed by the ExoMars rover mission in 2020[7] —also to be launched with a Russian Proton rocket.

As of January 2016, the 600 kg descent module Schiaparelli and orbiter have completed testing and are being integrated to a Proton rocket at the Baikonur cosmodrome in Kazakhstan.[32] The launch is scheduled for 14 March 2016.

Specifications

The proposed specifications are:[33]

Dimensions
Propulsion
Power
Batteries
Communication
Thermal control
Mass
Payload

Science

Scale model of ExoMars Trace Gas Orbiter displayed during Paris Air Show 2015

The TGO will separate from the ExoMars stationary lander and provide it with telecommunication relay for 8 sols after landing. Then the TGO will aerobrake for seven months into a more circular orbit for science observations and will provide communications relay for the ExoMars rover to be launched in 2020, and will continue serving as a relay satellite for future landed missions until 2022.[2]

The mission will characterise spatial, temporal variation, and localization of sources for a broad list of atmospheric trace gases:

Detection

Nature of the methane source requires measurements of a suite of trace gases in order to characterize potential biochemical and geochemical processes at work. The orbiter has very high sensitivity to (at least) the following molecules and their isotopomers: water (H2O), hydroperoxyl (HO2), nitrogen dioxide (NO2), nitrous oxide (N2O), methane (CH4), acetylene (C2H2), ethylene (C2H4), ethane (C2H6), formaldehyde (H2CO), hydrogen cyanide (HCN), hydrogen sulfide (H2S), carbonyl sulfide (OCS), sulfur dioxide (SO2), hydrogen chloride (HCl), carbon monoxide (CO) and ozone (O3). Detection sensitivities are at levels of 100 parts per trillion, improved to 10 parts per trillion or better by averaging spectra which could be taken at several spectra per second.[34]

Characterization
Localization

Payload

Like the Mars Reconnaissance Orbiter, the Trace Gas Orbiter is a hybrid science-telecom orbiter.[35] Its science payload mass is about 115 kg and consist of:[36]

NOMAD and ACS will provide the most extensive spectral coverage of Martian atmospheric processes so far.[35][39] Twice per orbit, at local sunrise and sunset, they will be able to observe the Sun as it shines through the atmosphere. Detection of atmospheric trace species at parts-per-billion (ppb) level will be possible.

Relay telecommunications

Due to the challenges of entry, descent, and landing, Mars landers are highly constrained in mass, volume, and power. For landed missions, this places severe constraints on antenna size and transmission power, which in turn greatly reduce direct-to-Earth communication capability in comparison to orbital spacecraft. As an example, the capability downlinks on Spirit and Opportunity have only 1/600th the capability of the Mars Reconnaissance Orbiter downlink. Relay communication addresses this problem by allowing Mars surface spacecraft to communicate using higher data rates over short-range links to nearby Mars orbiters, while the orbiter takes on the task of communicating over the long-distance link back to Earth. This relay strategy offers a variety of key benefits to Mars landers: increased data return volume, reduced energy requirements, reduced communications system mass, increased communications opportunities, robust critical event communications and in situ navigation aide.[40] NASA provided an Electra telecommunications relay and navigation instrument to assure communications between probes and rovers on the surface of Mars and controllers on Earth.[41] The TGO will provide the EDM lander and ExoMars rover with telecommunication relay and will continue serving as a relay satellite for future landed missions until 2022.[2]

See also

References

  1. "ExoMars Orbiter and EDM Mission (2016)". ESA. 13 March 2014. Retrieved 2015-09-04.
  2. 1 2 3 Allen, Mark; Witasse, Olivier (June 16, 2011), "2016 ESA/NASA ExoMars Trace Gas Orbiter", MEPAG June 2011, Jet Propulsion Laboratory (PDF)
  3. "Mission Story:2016 EXOMARS Mission- Trace Gas Orbiter and EDM". Planex News. 30 June 2015. Retrieved 2015-09-04.
  4. "Russian, EU Space Agencies Propose to Delay Joint Mission to Mars". Sputnik News (Moskow). 18 September 2015. Retrieved 2015-09-19.
  5. J. L. Vago (10 September 2009), "Mars Panel Meeting" (PDF), Planetary Science Decadal Survey (PDF), Arizona State University, Tempe (USA): ESA
  6. 1 2 MEPAG Report to the Planetary Science Subcommittee Author: Jack Mustard, MEPAG Chair. July 9, 2009 (pp. 3)
  7. 1 2 "Money Troubles May Delay Europe-Russia Mars Mission". Agence France-Presse (Industry Week). 15 January 2016. Retrieved 2016-01-16.
  8. Mars Trace Gas Mission (September 10, 2009)
  9. Mumma, Michael J.; Villanueva, Geronimo L.; Novak, Robert E.; Hewagama, Tilak; Bonev, Boncho P.; Disanti, Michael A.; Mandell, Avi M.; Smith, Michael D. (February 20, 2009). "Strong Release of Methane on Mars in Northern Summer 2003" (PDF). Science 323 (5917): 1041–1045. Bibcode:2009Sci...323.1041M. doi:10.1126/science.1165243. PMID 19150811.
  10. Hand, Eric (October 21, 2008). "Plumes of methane identified on Mars" (PDF). Nature News. Retrieved August 2, 2009.
  11. Making Sense of Mars Methane (June 2008)
  12. Steigerwald, Bill (January 15, 2009). "Martian Methane Reveals the Red Planet is not a Dead Planet". NASA's Goddard Space Flight Center (NASA). Retrieved January 24, 2009.
  13. Howe,, K. L.; Gavin, P.; Goodhart, T. and Kral, T. A. Methane Production by Methanogens in Perchlorate-Supplemented Media. (PDF). 40th Lunar and Planetary Science Conference (2009).
  14. Levin, Gilbert V. Levin; Patricia Ann Straat (September 3, 2009). "Methane and life on Mars". Proc. SPIE. Proceedings of SPIE 7441 (74410D): 74410D. doi:10.1117/12.829183.
  15. Rincon, Paul (July 9, 2009). "Agencies outline Mars initiative". BBC News. Retrieved July 26, 2009.
  16. "NASA orbiter to hunt for source of Martian methane in 2016". Thaindian News. March 6, 2009. Retrieved July 26, 2009.
  17. Mars Trace Gas Mission - Science Rationale & Concept (10 September 2009)
  18. 1 2 "Report to MEPAG on the ESA-NASA Joint Instrument Definition Team (JIDT) for the Proposed 2016 Orbiter-Carrier" (PDF). NASA. 29 July 2009. Retrieved 2015-09-04.
  19. 1 2 "ESA Proposes Two ExoMars Missions". Michael A. Taverna (Aviation Week). October 19, 2009. Retrieved 2009-10-30.
  20. NASA Could Take Role in European ExoMars Mission June 19, 2009
  21. Amos, Jonathan (12 October 2009). "Europe's Mars plans move forward". BBC News. Retrieved 2009-10-12.
  22. "ESA Proposes Two ExoMars Missions". Michael A. Taverna (Aviation Week). October 19, 2009. Retrieved 2009-10-23.
  23. "ExoMars Trace Gas Orbiter (TGO)". European Space Agency. 6 January 2012. Retrieved 2012-03-19.
  24. Aviation Week (February 14, 2012)
  25. "Experts React to Obama Slash to NASA's Mars and Planetary Science Exploration". Ken Kremr (Universe Today). February 1, 2012. Retrieved 2012-02-18.
  26. "Have Europe's Martian exploration plans been derailed by America?". Megan Whewell (MSN News). 15 February 2012. Retrieved 2012-02-15.
  27. "Europe Joins Russia on Robotic ExoMars". Amy Svitak (Aviation Week). Mar 16, 2012. Retrieved 2012-03-16.
  28. "ESA Ruling Council OKs ExoMars Funding". Peter B. de Selding (Space News). 15 March 2012. Retrieved 2012-03-16.
  29. "NASA drops ExoMars missions in 2013 budget". Optics. 15 February 2012. Retrieved 2012-02-15.
  30. Spacewatch: Uncertainties for ExoMars
  31. "Europe still keen on Mars missions". Jonathan Amos (BBC News). 15 March 2012. Retrieved 2012-03-16.
  32. "ExoMars 2016 Schiaparelli Module in Baikonur". ESA (SpaceRef). 6 January 2016. Retrieved 2016-01-06.
  33. "ExoMars Trace Gas Orbiter (TGO)". European Space Agency (ESA). 12 July 2012. Retrieved 2014-03-08.
  34. Vandaele, A. C.; et al., NOMAD, a spectrometer suite for nadir and solar occultation observations on the ExoMars Trace Gas Orbiter (PDF), Institut des NanoSciences de Paris, retrieved 2015-09-04
  35. 1 2 J Vago et al., "ExoMars, ESA’s next step in Mars exploration", ESA Bulletin magazine, number 155, August 2013, pages 12-23
  36. "ExoMars Trace Gas Orbiter Instruments". ESA. 20 February 2014. Retrieved 2014-03-08.
  37. Europe to invest 12 bln euros in a new space Odyssey, by Olga Zakutnyaya. Space Daily, 25 November 2012.
  38. 1 2 "Russia to Construct Landing Pad for Russian-European "ExoMars-2018" Space Mission". RIA Novosti (Russia). 4 August 2014. Retrieved 2014-08-05.
  39. "Europe". Jonathan Amos (BBC News). 18 June 2013. Retrieved 2013-06-18.
  40. Relay Orbiters for Enhancing and Enabling Mars In Situ Exploration (September 15, 2009)
  41. "U.S., Europe Won't Go It Alone in Mars Exploration". Peter B. de Selding (Spacew News). 26 September 2012. Retrieved 2012-09-27.

External links

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