Kazachok

The ExoMars Kazachok (Russian: Казачок; formerly ExoMars 2020 Surface Platform[2]) is a planned robotic Mars lander led by Roscosmos, part of the ExoMars 2022 joint mission with the European Space Agency. Kazachok translates as "Little Cossack", and is also the name of a Russian folk dance.

Kazachok lander
NamesExoMars 2020 Surface Platform[1][2]
Mission typeMars lander and rover
OperatorRoscosmos and ESA
Websiteexploration.esa.int/web/mars/-/56933-exomars-2020-surface-platform
Mission durationPlanned: 2 Earth years[3]
Spacecraft properties
ManufacturerLavochkin
Launch massLander: 827.9 kg (1,825 lb)
Rover: 310 kg (680 lb)
Payload massLander: 45 kg (99 lb)
PowerSolar panels[4]
Start of mission
Launch dateAugust–October 2022[5]
RocketProton-M/Briz-M[6]
Launch siteBaikonur
ContractorKhrunichev
Mars lander
Landing dateApril–July 2023[7]
Landing siteOxia Planum
ExoMars programme
 

The plan calls for a Russian Proton-M rocket to launch the Russian-built lander that will deliver the Rosalind Franklin rover to the surface of Mars.[8] Once safely landed, Kazachok will deploy the rover and will start a one Earth-year mission to investigate the surface environment at the landing site.[9]

The spacecraft was scheduled to launch in 2020 and land on Mars in mid 2021,[8] but due to delays in European and Russian industrial activities and deliveries of the scientific payload, it was moved to the launch window in August–October 2022.[5]

Scientific instruments

The Kazachok lander project is led by the Roscosmos, but will also include two ESA instruments and four components in Russian instruments. The science payload mass is about 45 kg and consists of: [9][3]

  • The Lander Radioscience experiment (LaRa) will study the internal structure of Mars, will help to understand the sublimation/condensation cycle of atmospheric CO2, and will make precise measurements of the rotation and orientation of the planet by monitoring two-way Doppler frequency shifts between the lander and Earth.[10] It will also detect variations in angular momentum due to the redistribution of masses, such as the migration of ice from the polar caps to the atmosphere. Developed by Belgium.
  • The Habitability, Brine, Irradiation and Temperature (HABIT) package will investigate the amount of water vapour in the atmosphere, daily and seasonal variations in ground and air temperatures, and the UV radiation environment. Developed by Sweden.
  • Meteorological package (METEO-M). Developed by Russia. The instrument will incorporate the following sensor packages:
    • Pressure and humidity sensors (METEO-P, METEO-H).[11] Developed by Finland. The instrument has extensive heritage from those in the Curiosity rover, Schiaparelli lander and Phoenix lander.[11]
    • Radiation and dust sensors (RDM). Developed by Spain.
    • Anisotropic magneto-resistance (AMR) sensor to measure magnetic fields. Developed by Spain.
  • A magnetometer named MAIGRET, developed by Russia. The instrument will incorporate the Wave Analyser Module (WAM),[12] developed by the Czech Republic.
  • A set of cameras to characterise the landing site environment (TSPP). Developed by Russia.
  • Instrument interface and memory unit (BIP). Developed by Russia.
  • An IR Fourier spectrometer to study the atmosphere (FAST). Developed by Russia.
  • Active Detection of Radiation of Nuclei-ExoMars (ADRON-EM). Developed by Russia.
  • Multi-channel Diode-Laser Spectrometer for atmospheric investigations (M-DLS). Developed by Russia.
  • Radio thermometer for soil temperatures (PAT-M). Developed by Russia.
  • Dust particle size, impact, and atmospheric charging instrument suite (Dust Suite). Developed by Russia.
  • A seismometer named SEM. Developed by Russia.
  • Gas chromatography–mass spectrometry for atmospheric analysis (MGAK). Developed by Russia.
Power source

The science and communication instruments on the lander will be powered by solar panels and rechargeable batteries.[4] The automated voltage power system is being developed and build by ISS Reshetnev.[4]

Russia previously evaluated the option of using a radioisotope thermoelectric generator (RTG) to power the science instruments,[13] and a radioisotope heater unit (RHU) to provide thermal control while on the frozen Martian surface.[14]

Landing site selection

Oxia Planum, near the equator, is a proposed landing site for its smooth surface and potential to preserve biosignatures

After a review by an ESA-appointed panel, a short list of four sites was formally recommended in October 2014 for further detailed analysis:[15][16]

On 21 October 2015, Oxia Planum was chosen as the preferred landing site for the ExoMars rover assuming a 2018 launch. Since the launch was postponed to 2020, Aram Dorsum and Mawrth Vallis are also being considered.[17][18] ESA convened further workshops to re-evaluate the three remaining options and in March 2017 selected two sites to study in detail:

After deliberation, ESA selected Oxia Planum to be the landing site in November 2018.[19][20]

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References

  1. "ExoMars 2018 Surface Platform Experiment Proposal Information Package (pdf, 8.3 MB)". European Space Agency. 31 March 2015. Retrieved 4 October 2016.
  2. Meet 'Kazachok': Landing Platform for ExoMars Rover Gets a Name. Mike Wall, Spaceflight. 22 March 2019.
  3. ExoMars-2020 Surface Platform scientific investigation. Daniel Rodionov, Lev Zelenyi, Oleg Korablev, Ilya Chuldov and Jorge Vago. EPSC Abstracts. Vol. 12, EPSC2018-732, European Planetary Science Congress 2018.
  4. ISS-Reshetnev chosen for ExoMars-2020 project. ISS-Reshetnev. 23 November 2016.
  5. "N° 6–2020: ExoMars to take off for the Red Planet in 2022" (Press release). ESA. 12 March 2020. Retrieved 12 March 2020.
  6. Krebs, Gunter. "ExoMars". Gunter's Space Page. Retrieved 12 March 2020.
  7. @ESA_ExoMars (12 March 2020). "#ExoMars to take off for the Red Planet in 2022. Check out the new timeline for mission success on the Red Planet! pbs.twimg.com/media/ES52icEX0AELyns?format=jpg" (Tweet). Retrieved 13 March 2020 via Twitter.
  8. "Russia and Europe Team Up for Mars Missions". Space.com. 14 March 2013. Retrieved 24 January 2016.
  9. "Exomars 2018 surface platform". European Space Agency. Retrieved 14 March 2016.
  10. LaRa (Lander Radioscience) on the ExoMars 2020 Surface Platform. (PDF) Véronique Dehant, Sébastien Le Maistre, Rose-Marie Baland, et al. EPSC Abstracts. Vol. 12, EPSC2018-31, 2018. European Planetary Science Congress 2018.
  11. Controller for in-situ pressure and humidity measurements on board ExoMars 2020 Surface Platform. Nikkanen, Timo; Genzer, Maria; Hieta, Maria; Harri, Ari-Matti; Haukka, Harri; Polkko, Jouni; Meskanen, Matias. 20th EGU General Assembly, EGU2018, Proceedings from the conference held 4-13 April, 2018 in Vienna, Austria, p.7507. April 2018.
  12. Wave analyzer module of the MAIGRET instrument onboard Surface Platform of the ExoMars 2020 mission. Santolik, Ondrej; Kolmasova, Ivana; Uhlir, Ludek; Skalsky, Alexander; Soucek, Jan; Lan, Radek. 42nd COSPAR Scientific Assembly. Held 14-22 July 2018, in Pasadena, California, USA, Abstract id. B4.2-39-18. July 2018.
  13. Amos, Jonthan (21 June 2013). "Looking forward to Europe's 'seven minutes of terror'". BBC News.
  14. Zak, Anatoly (3 March 2016). "ExoMars 2018". Russian Space Web. Retrieved 15 March 2016.
  15. "Four Candidate Landing Sites for ExoMars 2018". ESA. Space Ref. 1 October 2014. Retrieved 1 October 2014.
  16. "Recommendation for the Narrowing of ExoMars 2018 Landing Sites". ESA. 1 October 2014. Retrieved 1 October 2014.
  17. Amos, Jonathan (21 October 2015). "ExoMars rover: Landing preference is for Oxia Planum". BBC News. Retrieved 22 October 2015.
  18. Atkinson, Nancy (21 October 2015). "Scientists Want ExoMars Rover to Land at Oxia Planum". Universe Today. Retrieved 22 October 2015.
  19. "Landing Site". ESA. Retrieved 12 March 2020.
  20. Amos, Jonathan (9 November 2018). "ExoMars: Life-detecting robot to be sent to Oxia Planum". BBC News. Retrieved 12 March 2020.

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