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BepiColombo

January 07, 2023

BepiColombo is a joint mission of the European Space Agency (ESA) and the Japan Aerospace Exploration Agency (JAXA) to the planet Mercury.[4] The mission comprises two satellites launched together: the Mercury Planetary Orbiter (MPO) and Mio (Mercury Magnetospheric Orbiter, MMO).[5] The mission will perform a comprehensive study of Mercury, including characterization of its magnetic field, magnetosphere, and both interior and surface structure. It was launched on an Ariane 5[2] rocket on 20 October 2018 at 01:45 UTC, with an arrival at Mercury planned for on 5 December 2025, after a flyby of Earth, two flybys of Venus, and six flybys of Mercury.[1][6] The mission was approved in November 2009, after years in proposal and planning as part of the European Space Agency's Horizon 2000+ programme;[7] it is the last mission of the programme to be launched.[8]

BepiColombo
Artist's depiction of the BepiColombo mission, with the Mercury Planetary Orbiter (left) and Mercury Magnetospheric Orbiter (right)
Mission typePlanetary science
Operator
COSPAR ID2018-080A
SATCAT no.43653
Mission durationCruise: 7 years (planned)
Science phase: 1 year (planned)
4 years, 2 months and 15 days (in progress)
Spacecraft properties
Manufacturer
Launch mass4,100 kg (9,000 lb) [1]
BOL massMPO: 1,230 kg (2,710 lb)
Mio: 255 kg (562 lb) [1]
Dry mass2,700 kg (6,000 lb) [1]
DimensionsMPO: 2.4 m × 2.2 m × 1.7 m (7 ft 10 in × 7 ft 3 in × 5 ft 7 in)
Mio: 1.8 m × 1.1 m (5 ft 11 in × 3 ft 7 in) [1]
PowerMPO: 150 watts
Mio: 90 watts
Start of mission
Launch date20 October 2018, 01:45 UTC
RocketAriane 5 ECA (VA245)[2]
Launch siteCentre Spatial Guyanais, ELA-3[3]
ContractorArianespace
Flyby of Earth (gravity assist)
Closest approach10 April 2020, 04:25 UTC
Distance12,677 km (7,877 mi)
Flyby of Venus (gravity assist)
Closest approach15 October 2020, 03:58 UTC
Distance10,720 km (6,660 mi)
Flyby of Venus (gravity assist)
Closest approach10 August 2021, 13:51 UTC
Distance552 km (343 mi)
Flyby of Mercury (gravity assist)
Closest approach1 October 2021, 23:34:41 UTC
Distance199 km (124 mi)
Flyby of Mercury (gravity assist)
Closest approach23 June 2022, 09:44 UTC
Distance200 km (120 mi)
Mercury orbiter
Spacecraft componentMercury Planetary Orbiter
(MPO)
Orbital insertion5 December 2025 (planned)
Orbital parameters
Perihermion altitude480 km (300 mi)
Apohermion altitude1,500 km (930 mi)
Inclination90,0°
Mercury orbiter
Spacecraft componentMercury Magnetospheric Orbiter
(MMO)
Orbital insertion5 December 2025 (planned)
Orbital parameters
Perihermion altitude590 km (370 mi)
Apohermion altitude11,640 km (7,230 mi)
Inclination90.0°

ESA Solar System insignia for BepiColombo  

Names

BepiColombo is named after Giuseppe "Bepi" Colombo (1920–1984), a scientist, mathematician and engineer at the University of Padua, Italy, who first proposed the interplanetary gravity assist manoeuvre used by the 1974 Mariner 10 mission, a technique now used frequently by planetary probes.

Mio, the name of the Mercury Magnetospheric Orbiter, was selected from thousands of suggestions by the Japanese public. In Japanese, Mio means a waterway, and according to JAXA, it symbolizes the research and development milestones reached thus far, and wishes for safe travel ahead. JAXA said the spacecraft will travel through the solar wind just like a ship traveling through the ocean.[5] In Chinese and Japanese, Mercury is known as the "water star" (水星) according to wǔxíng.

Following its Earth flyby in April 2020, BepiColombo was briefly mistaken for a near-Earth asteroid, receiving the provisional designation 2020 GL2.[9][10][11][12]

Mission

The mission involves three components, which will separate into independent spacecraft upon arrival at Mercury.[13]

  • Mercury Transfer Module (MTM) for propulsion, built by ESA.
  • Mercury Planetary Orbiter (MPO) built by ESA.
  • Mercury Magnetospheric Orbiter (MMO) or Mio built by JAXA.

During the launch and cruise phases, these three components are joined together to form the Mercury Cruise System (MCS).

The prime contractor for ESA is Airbus Defence and Space.[14] ESA is responsible for the overall mission, the design, development assembly and test of the propulsion and MPO modules, and the launch. The two orbiters, which are operated by mission controllers based in Darmstadt, Germany, were successfully launched together on 20 October 2018.[15] The launch took place on Ariane flight VA245 from Europe’s Spaceport in Kourou, French Guiana.[16] The spacecraft will have a seven-year interplanetary cruise to Mercury using solar-electric propulsion (ion thrusters) and gravity assists from Earth, Venus and eventual gravity capture at Mercury.[1] ESA's Cebreros, Spain 35-metre ground station is planned to be the primary ground facility for communications during all mission phases.

Expected to arrive in Mercury orbit on 5 December 2025, the Mio and MPO satellites will separate and observe Mercury in collaboration for one year, with a possible one-year extension.[1] The orbiters are equipped with scientific instruments provided by various European countries and Japan. The mission will characterize the solid and liquid iron core (34 of the planet's radius) and determine the size of each.[17] The mission will also complete gravitational and magnetic field mappings. Russia provided gamma ray and neutron spectrometers to verify the existence of water ice in polar craters that are permanently in shadow from the Sun's rays.

Mercury is too small and hot for its gravity to retain any significant atmosphere over long periods of time, but it has a "tenuous surface-bounded exosphere"[18] containing hydrogen, helium, oxygen, sodium, calcium, potassium and other trace elements. Its exosphere is not stable as atoms are continuously lost and replenished from a variety of sources. The mission will study the exosphere composition and dynamics, including generation and escape.

Objectives

The main objectives of the mission are:[3][19]

Design

 
Planned orbits for Mio and MPO satellites, the two probes of the BepiColombo mission

The stacked spacecraft will take seven years to position itself to enter Mercury orbit. During this time it will use solar-electric propulsion and nine gravity assists, flying past the Earth and Moon in April 2020, Venus in 2020 and 2021, and six Mercury flybys between 2021 and 2025.[1]

The stacked spacecraft left Earth with a hyperbolic excess velocity of 3.475 km/s (2.159 mi/s). Initially, the craft was placed in a heliocentric orbit similar to that of Earth. After both the spacecraft and Earth completed one and a half orbits, it returned to Earth to perform a gravity-assist maneuver and is deflected towards Venus. Two consecutive Venus flybys reduce the perihelion near to the Sun–Mercury distance with almost no need for thrust. A sequence of six Mercury flybys will lower the relative velocity to 1.76 km/s (1.09 mi/s). After the fourth Mercury flyby, the craft will be in an orbit similar to that of Mercury and will remain in the general vicinity of Mercury (see [1]). Four final thrust arcs reduce the relative velocity to the point where Mercury will "weakly" capture the spacecraft on 5 December 2025 into polar orbit. Only a small maneuver is needed to bring the craft into an orbit around Mercury with an apocentre of 178,000 km. The orbiters then separate and will adjust their orbits using chemical thrusters.[22][23]

History

The BepiColombo mission proposal was selected by ESA in 2000. A request for proposals for the science payload was issued in 2004.[24] In 2007, Astrium was selected as the prime contractor, and Ariane 5 chosen as the launch vehicle.[24] The initial target launch of July 2014 was postponed several times, mostly because of delays on the development of the solar electric propulsion system.[24] The total cost of the mission was estimated in 2017 as US$2 billion.[25]

Schedule

 
Animation of BepiColombo's trajectory from 20 October 2018 to 2 November 2025
   BepiColombo ·   Earth ·   Venus ·   Mercury ·   Sun
For more detailed animation, see this video
Sequence of images taken during the second Mercury flyby
 
Animation of BepiColombo's trajectory around Mercury

As of 2021, the mission schedule is:[1]

Date Event Comment
20 October 2018, 01:45 UTC Launch
10 April 2020,
04:25 UTC 		Earth flyby 1.5 years after launch
15 October 2020, 03:58 UTC First Venus flyby According to Johannes Benkhoff of ESA, the probe may possibly be capable of detecting phosphine – the chemical allegedly discovered in the Venusian atmosphere in September 2020 – during this and the following flyby. He stated that "we do not know if our instrument is sensitive enough".[26] On 15 October 2020, the ESA reported the flyby was a success.[27]
10 August 2021,
13:51 UTC 		Second Venus flyby 1.35 Venus years after first Venus flyby. Flyby was a success, and saw BepiColombo come within 552 km of Venus' surface.[28][29]
1 October 2021, 23:34:41 UTC First Mercury flyby Passed 199 km from Mercury's surface.[30] Occurred on what would have been the 101st birthday of Giuseppe Colombo.
23 June 2022, 09:44 UTC Second Mercury flyby 2 orbits (3.00 Mercury years) after 1st Mercury flyby. Closest approach of about 200 km altitude.[31]
20 June 2023 Third Mercury flyby >3 orbits (4.12 Mercury years) after 2nd Mercury flyby
5 September 2024 Fourth Mercury flyby ~4 orbits (5.04 Mercury years) after 3rd Mercury flyby
2 December 2024 Fifth Mercury flyby 1 orbit (1.00 Mercury year) after 4th Mercury flyby
9 January 2025 Sixth Mercury flyby ~0.43 orbits (0.43 Mercury years) after 5th Mercury flyby
5 December 2025 Mercury orbit insertion Spacecraft separation; 3.75 Mercury years after 6th Mercury flyby
14 March 2026 MPO in final science orbit 1.13 Mercury years after orbit insertion
1 May 2027 End of nominal mission 5.82 Mercury years after orbit insertion
1 May 2028 End of extended mission 9.98 Mercury years after orbit insertion
 
Timeline of BepiColombo from 20 October 2018 to 2 November 2025. Red circle indicates flybys.

Components

Mercury Transfer Module

 
Earth flyby on 10 April 2020
BepiColombo, imaged at Northolt Branch Observatories, 16 hours after the Earth flyby. The bright satellite passing by is INSAT-2D, a defunct geostationary satellite.
QinetiQ T6 Performance [32][33]
Type Kaufman Ion Engine
Units on board 4 [34][35]
Diameter 22 cm (8.7 in)
Max. thrust 145 mN each
Specific impulse
(Isp)		 4300 seconds
Propellant Xenon
Total power 4628 W

The Mercury Transfer Module (MTM) is located at the base of the stack. Its role is to carry the two science orbiters to Mercury and to support them during the cruise.

The MTM is equipped with a solar electric propulsion system as the main spacecraft propulsion. Its four QinetiQ-T6 ion thrusters operate singly or in pairs for a maximum combined thrust of 290 mN,[36] making it the most powerful ion engine array ever operated in space. The MTM supplies electrical power for the two hibernating orbiters as well as for its solar electric propulsion system thanks to two 14-meter-long solar panels.[37] Depending on the probe's distance to the Sun, the generated power will range between 7 and 14 kW, each T6 requiring between 2.5 and 4.5 kW according to the desired thrust level.

The solar electric propulsion system has typically very high specific impulse and low thrust. This leads to a flight profile with months-long continuous low-thrust braking phases, interrupted by planetary gravity assists, to gradually reduce the velocity of the spacecraft. Moments before Mercury orbit insertion, the MTM will be jettisoned from the spacecraft stack.[37] After separation from the MTM, the MPO will provide Mio all necessary power and data resources until Mio is delivered to its mission orbit; separation of Mio from MPO will be accomplished by spin-ejection.

Mercury Planetary Orbiter

 
Mercury Planetary Orbiter in ESTEC before stacking
 
Radio testing of BepiColombo orbiter

The Mercury Planetary Orbiter (MPO) has a mass of 1,150 kg (2,540 lb) and uses a single-sided solar array capable of providing up to 1000 watts and featuring Optical Solar Reflectors to keep its temperature below 200 °C (392 °F). The solar array requires continuous rotation keeping the Sun at a low incidence angle in order to generate adequate power while at the same time limiting the temperature.[37]

The MPO will carry a payload of 11 instruments, comprising cameras, spectrometers (IR, UV, X-ray, γ-ray, neutron), a radiometer, a laser altimeter, a magnetometer, particle analysers, a Ka-band transponder, and an accelerometer. The payload components are mounted on the nadir side of the spacecraft to achieve low detector temperatures, apart from the MERTIS and PHEBUS spectrometers located directly at the main radiator to provide a better field of view.[37]

A high-temperature-resistant 1.0 m (3 ft 3 in) diameter high-gain antenna is mounted on a short boom on the zenith side of the spacecraft. Communications will be on the X-band and Ka-band with an average bit rate of 50 kbit/s and a total data volume of 1550 Gbit/year. ESA's Cebreros, Spain 35-metre ground station is planned to be the primary ground facility for communications during all mission phases.[37]

Science payload

The science payload of the Mercury Planetary Orbiter consists of eleven instruments:[38][39]

Mio (Mercury Magnetospheric Orbiter)

 
Mio in ESTEC before stacking

Mio, or the Mercury Magnetospheric Orbiter (MMO), developed and built mostly by Japan, has the shape of a short octagonal prism, 180 cm (71 in) long from face to face and 90 cm (35 in) high.[3][45] It has a mass of 285 kg (628 lb), including a 45 kg (99 lb) scientific payload consisting of 5 instrument groups, 4 for plasma and dust measuring run by investigators from Japan, and one magnetometer from Austria.[3][46][47]

Mio will be spin stabilized at 15 rpm with the spin axis perpendicular to the equator of Mercury. It will enter a polar orbit at an altitude of 590 × 11,640 km (370 × 7,230 mi), outside of MPO's orbit.[46] The top and bottom of the octagon act as radiators with louvers for active temperature control. The sides are covered with solar cells which provide 90 watts. Communications with Earth will be through a 0.8 m (2 ft 7 in) diameter X-band phased array high-gain antenna and two medium-gain antennas operating in the X-band. Telemetry will return 160 Gb/year, about 5 kbit/s over the lifetime of the spacecraft, which is expected to be greater than one year. The reaction and control system is based on cold gas thrusters. After its release in Mercury orbit, Mio will be operated by Sagamihara Space Operation Center using Usuda Deep Space Center's 64 m (210 ft) antenna located in Nagano, Japan.[38]

Science payload

Mio carries five groups of science instruments with a total mass of 45 kg (99 lb):[3][38]

Mercury Surface Element (cancelled)

The Mercury Surface Element (MSE) was cancelled in 2003 due to budgetary constraints.[8] At the time of cancellation, MSE was meant to be a small, 44 kg (97 lb), lander designed to operate for about one week on the surface of Mercury.[22] Shaped as a 0.9 m (2 ft 11 in) diameter disc, it was designed to land at a latitude of 85° near the terminator region. Braking manoeuvres would bring the lander to zero velocity at an altitude of 120 m (390 ft) at which point the propulsion unit would be ejected, airbags inflated, and the module would fall to the surface with a maximum impact velocity of 30 m/s (98 ft/s). Scientific data would be stored onboard and relayed via a cross-dipole UHF antenna to either the MPO or Mio. The MSE would have carried a 7 kg (15 lb) payload consisting of an imaging system (a descent camera and a surface camera), a heat flow and physical properties package, an alpha particle X-ray spectrometer, a magnetometer, a seismometer, a soil penetrating device (mole), and a micro-rover.[49]

Artwork

As with the Hayabusa2 mission, the BepiColombo mission is the topic of artwork. The manga artist Masayuki Ishikawa created a piece featuring the character Mercury from the manga Madowanai Hoshi, as well as the BepiColombo spacecraft.[50][51]

See also

References

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  2. ^ a b "BepiColombo's first image from space". ESA. 10 October 2018.
  3. ^ a b c d e "MIO/BepiColombo". JAXA. 2018. Retrieved 9 July 2018.
  4. ^ Amos, Jonathan (18 January 2008). "European probe aims for Mercury". BBC News. Retrieved 21 January 2008.
  5. ^ a b "MIO – Mercury Magnetospheric Orbiter's New Name" (Press release). JAXA. 8 June 2018. Retrieved 9 June 2018.
  6. ^ "BepiColombo Launch Rescheduled for October 2018". ESA. 25 November 2016. Retrieved 14 December 2016.
  7. ^ "BepiColombo Overview". ESA. 5 September 2016. Retrieved 13 March 2017.
  8. ^ a b "Critical Decisions on Cosmic Vision" (Press release). ESA. 7 November 2003. No. 75-2003. Retrieved 14 December 2016.
  9. ^ . Minor Planet Center. 13 April 2020. Archived from the original on 13 April 2020.
  10. ^ . Minor Planet Center. 13 April 2020. Archived from the original on 13 April 2020.
  11. ^ "MPEC 2020-G97 : DELETION OF 2020 GL2". Minor Planet Center. 13 April 2020. Retrieved 14 April 2020.
  12. ^ "BepiColombo flies by Earth". Europlanet Society. 10 April 2020. Retrieved 24 June 2022. The data collected for this image, even though it was submitted to the Minor Planet Center as artificial satellite 2018-080A (BepiColombo’s official designation), led to it being mistaken for a Near Earth asteroid. The “discovery”, announced by the Minor Planet Center as asteroid 2020 GL2, was retracted soon after. This was the third time a spacecraft had been mistakenly announced as a “new asteroid” during an Earth flyby, after Rosetta a.k.a. 2007 VN84 and Gaia a.k.a. 2015 HP116. Incidentally, all three of these are ESA missions.
  13. ^ Hayakawa, Hajime; Maejima, Hironori (2011). BepiColombo Mercury Magnetospheric Orbiter (MMO) (PDF). 9th IAA Low-Cost Planetary Missions Conference. 21–23 June 2011, Laurel, Maryland.
  14. ^ "BepiColombo to Enter Implementation Phase". ESA. 26 February 2007.
  15. ^ Amos, Jonathan (20 October 2018). "Blast-off for BepiColombo on mission to Mercury". BBC News. Retrieved 20 October 2018.
  16. ^ "Watch BepiColombo launch". European Space Agency. 16 October 2018. Retrieved 8 December 2021.
  17. ^ Science with BepiColombo ESA, Accessed: 23 October 2018
  18. ^ Domingue, Deborah L.; Koehn, Patrick L.; et al. (August 2007). "Mercury's Atmosphere: A Surface-Bounded Exosphere". Space Science Reviews. 131 (1–4): 161–186. Bibcode:2007SSRv..131..161D. doi:10.1007/s11214-007-9260-9. S2CID 121301247.
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  20. ^ "BepiColombo - Testing general relativity". ESA. 4 July 2003. Archived from the original on 7 February 2014. Retrieved 7 February 2014.
  21. ^ Einstein's general relativity reveals new quirk of Mercury's orbit Emily Conover Science News 11 April 2018
  22. ^ a b "BepiColombo". National Space Science Data Center. NASA. 26 August 2014. Retrieved 6 April 2015.   This article incorporates text from this source, which is in the public domain.
  23. ^ "Mission Operations – Getting to Mercury". ESA. Retrieved 7 February 2014.
  24. ^ a b c BepiColombo: Joint Mission to Mercury Elizabeth Howell Space.com 21 October 2018
  25. ^ BepiColombo Mercury mission tested for journey into 'pizza oven' Stephen Clarke Spaceflight Now 17 July 2017
  26. ^ O'Callaghan, Jonathan. "In A Complete Fluke, A European Spacecraft Is About To Fly Past Venus – And Could Look For Signs Of Life". Forbes. Retrieved 16 September 2020.
  27. ^ "BepiColombo flies by Venus en route to Mercury". ESA. 15 October 2020. Retrieved 15 October 2020. The flyby itself was very successful", confirms Elsa. "The only difference to normal cruise phase operations is that near to Venus we have to temporarily close the shutter of any of the star trackers that are expected to be blinded by the planet, similar to closing your eyes to avoid looking at the Sun
  28. ^ "BepiColombo's second Venus flyby in images". European Space Agency. Retrieved 8 December 2021.
  29. ^ Pultarova, Tereza (11 August 2021). "Mercury-bound spacecraft snaps selfie with Venus in close flyby (photo)". Space.com. Retrieved 8 December 2021.
  30. ^ ESA Operations [@esaoperations] (2 October 2021). "At 01:34:41 CEST this morning, BepiColombo passed just 199 kilometres from the hot, rocky, innermost planet" (Tweet) – via Twitter.
  31. ^ "Second helpings of Mercury". European Space Agency. 24 June 2022. Retrieved 24 June 2022.
  32. ^ Qualification of the T6 Thruster for BepiColombo 12 August 2016 at the Wayback Machine R. A. Lewis, J. Pérez Luna, N. Coombs. 30th International Symposium on Space Technology and Science 34th International Electric Propulsion Conference and 6th Nano-satellite Symposium, Hyogo-Kobe, Japan, 4–10 July 2015
  33. ^ QinetiQ's T6 and T5 Ion Thruster Electric Propulsion System Architectures and Performances Mark Hutchins, Huw Simpson. 30th International Symposium on Space Technology and Science 34th International Electric Propulsion Conference and 6th Nano-satellite Symposium, Hyogo-Kobe, Japan, 4–10 July 2015
  34. ^ "T6 ion thruster firing". ESA. 27 April 2016. Retrieved 7 August 2019.
  35. ^ "T6 ion thrusters installed on BepiColombo". ESA. 26 April 2016. Retrieved 7 August 2019.
  36. ^ Clark, Stephen D.; Hutchins, Mark S.; et al. (2013). . 33rd International Electric Propulsion Conference 6–10 October 2013 Washington, D.C. IEPC-2013-133. Archived from the original on 20 December 2016.
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  38. ^ a b c "MMO (Mercury Magnetospheric Orbiter): Objectives". JAXA. 2011. Retrieved 7 February 2014.
  39. ^ "Mercury Planetary Orbiter – Instruments". ESA. 15 January 2008. Retrieved 6 February 2014.
  40. ^ a b "MPS: BepiColombo - SERENA".
  41. ^ "MPS: MIXS on BepiColombo".
  42. ^ Fraser, G.W.; Carpenter, J.D.; Rothery, D.A.; Pearson, J.F.; Martindale, A.; Huovelin, J.; Treis, J.; Anand, M.; Anttila, M.; Ashcroft, M.; Benkoff, J.; Bland, P.; Bowyer, A.; Bradley, A.; Bridges, J.; Brown, C.; Bulloch, C.; Bunce, E.J.; Christensen, U.; Evans, M.; Fairbend, R.; Feasey, M.; Giannini, F.; Hermann, S.; Hesse, M.; Hilchenbach, M.; Jorden, T.; Joy, K.; Kaipiainen, M.; Kitchingman, I.; Lechner, P.; Lutz, G.; Malkki, A.; Muinonen, K.; Näränen, J.; Portin, P.; Prydderch, M.; Juan, J. San; Sclater, E.; Schyns, E.; Stevenson, T.J.; Strüder, L.; Syrjasuo, M.; Talboys, D.; Thomas, P.; Whitford, C.; Whitehead, S. (2010). "The mercury imaging X-ray spectrometer (MIXS) on bepicolombo". Planetary and Space Science. 58 (1–2): 79–95. Bibcode:2010P&SS...58...79F. doi:10.1016/j.pss.2009.05.004. ISSN 0032-0633.
  43. ^ "SERENA". ESA. Retrieved 7 August 2019.
  44. ^ . Discovery Program. NASA. Archived from the original on 8 January 2017. Retrieved 7 January 2017.   This article incorporates text from this source, which is in the public domain.
  45. ^ Yamakawa, Hiroshi; Ogawa, Hiroyuki; et al. (January 2004). "Current status of the BepiColombo/MMO spacecraft design". Advances in Space Research. 33 (12): 2133–2141. Bibcode:2004AdSpR..33.2133Y. doi:10.1016/S0273-1177(03)00437-X.
  46. ^ a b "Mercury Exploration Project "BepiColombo"" (PDF). JAXA. 2014. Retrieved 6 April 2015.
  47. ^ "A pair of planetary Explorers at Mercury". esa.int. Retrieved 21 October 2018.
  48. ^ "MPPE".
  49. ^ "BepiColombo's lander". ESA. 20 February 2002. Retrieved 7 February 2014.
  50. ^ 石川雅之 (27 July 2018). "元絵は「みお」を追加してプロジェクトにご笑納いただきましたpic.twitter.com/fYhYUT7nif". @isk_ms (in Japanese). Retrieved 9 March 2020.
  51. ^ "【JAXA╳『惑わない星』】 水星探査機「みお(MIO)」プロジェクトサイエンティストと石川雅之の打ち上げ直前対談が実現!(Google Translate)". translate.google.com. Retrieved 9 March 2020.

External links

January 07, 2023
bepicolombo, joint, mission, european, space, agency, japan, aerospace, exploration, agency, jaxa, planet, mercury, mission, comprises, satellites, launched, together, mercury, planetary, orbiter, mercury, magnetospheric, orbiter, mission, will, perform, compr. BepiColombo is a joint mission of the European Space Agency ESA and the Japan Aerospace Exploration Agency JAXA to the planet Mercury 4 The mission comprises two satellites launched together the Mercury Planetary Orbiter MPO and Mio Mercury Magnetospheric Orbiter MMO 5 The mission will perform a comprehensive study of Mercury including characterization of its magnetic field magnetosphere and both interior and surface structure It was launched on an Ariane 5 2 rocket on 20 October 2018 at 01 45 UTC with an arrival at Mercury planned for on 5 December 2025 after a flyby of Earth two flybys of Venus and six flybys of Mercury 1 6 The mission was approved in November 2009 after years in proposal and planning as part of the European Space Agency s Horizon 2000 programme 7 it is the last mission of the programme to be launched 8 BepiColomboArtist s depiction of the BepiColombo mission with the Mercury Planetary Orbiter left and Mercury Magnetospheric Orbiter right Mission typePlanetary scienceOperatorESAJAXACOSPAR ID2018 080ASATCAT no 43653Mission durationCruise 7 years planned Science phase 1 year planned 4 years 2 months and 15 days in progress Spacecraft propertiesManufacturerAirbusISASLaunch mass4 100 kg 9 000 lb 1 BOL massMPO 1 230 kg 2 710 lb Mio 255 kg 562 lb 1 Dry mass2 700 kg 6 000 lb 1 DimensionsMPO 2 4 m 2 2 m 1 7 m 7 ft 10 in 7 ft 3 in 5 ft 7 in Mio 1 8 m 1 1 m 5 ft 11 in 3 ft 7 in 1 PowerMPO 150 wattsMio 90 wattsStart of missionLaunch date20 October 2018 01 45 UTCRocketAriane 5 ECA VA245 2 Launch siteCentre Spatial Guyanais ELA 3 3 ContractorArianespaceFlyby of Earth gravity assist Closest approach10 April 2020 04 25 UTCDistance12 677 km 7 877 mi Flyby of Venus gravity assist Closest approach15 October 2020 03 58 UTCDistance10 720 km 6 660 mi Flyby of Venus gravity assist Closest approach10 August 2021 13 51 UTCDistance552 km 343 mi Flyby of Mercury gravity assist Closest approach1 October 2021 23 34 41 UTCDistance199 km 124 mi Flyby of Mercury gravity assist Closest approach23 June 2022 09 44 UTCDistance200 km 120 mi Mercury orbiterSpacecraft componentMercury Planetary Orbiter MPO Orbital insertion5 December 2025 planned Orbital parametersPerihermion altitude480 km 300 mi Apohermion altitude1 500 km 930 mi Inclination90 0 Mercury orbiterSpacecraft componentMercury Magnetospheric Orbiter MMO Orbital insertion5 December 2025 planned Orbital parametersPerihermion altitude590 km 370 mi Apohermion altitude11 640 km 7 230 mi Inclination90 0 ESA Solar System insignia for BepiColombo Horizon 2000 Plus LISA PathfinderCHEOPS Contents 1 Names 2 Mission 2 1 Objectives 2 2 Design 2 3 History 2 4 Schedule 3 Components 3 1 Mercury Transfer Module 3 2 Mercury Planetary Orbiter 3 2 1 Science payload 3 3 Mio Mercury Magnetospheric Orbiter 3 3 1 Science payload 3 4 Mercury Surface Element cancelled 4 Artwork 5 See also 6 References 7 External linksNames EditBepiColombo is named after Giuseppe Bepi Colombo 1920 1984 a scientist mathematician and engineer at the University of Padua Italy who first proposed the interplanetary gravity assist manoeuvre used by the 1974 Mariner 10 mission a technique now used frequently by planetary probes Mio the name of the Mercury Magnetospheric Orbiter was selected from thousands of suggestions by the Japanese public In Japanese Mio means a waterway and according to JAXA it symbolizes the research and development milestones reached thus far and wishes for safe travel ahead JAXA said the spacecraft will travel through the solar wind just like a ship traveling through the ocean 5 In Chinese and Japanese Mercury is known as the water star 水星 according to wǔxing Following its Earth flyby in April 2020 BepiColombo was briefly mistaken for a near Earth asteroid receiving the provisional designation 2020 GL2 9 10 11 12 Mission EditThe mission involves three components which will separate into independent spacecraft upon arrival at Mercury 13 Mercury Transfer Module MTM for propulsion built by ESA Mercury Planetary Orbiter MPO built by ESA Mercury Magnetospheric Orbiter MMO or Mio built by JAXA During the launch and cruise phases these three components are joined together to form the Mercury Cruise System MCS The prime contractor for ESA is Airbus Defence and Space 14 ESA is responsible for the overall mission the design development assembly and test of the propulsion and MPO modules and the launch The two orbiters which are operated by mission controllers based in Darmstadt Germany were successfully launched together on 20 October 2018 15 The launch took place on Ariane flight VA245 from Europe s Spaceport in Kourou French Guiana 16 The spacecraft will have a seven year interplanetary cruise to Mercury using solar electric propulsion ion thrusters and gravity assists from Earth Venus and eventual gravity capture at Mercury 1 ESA s Cebreros Spain 35 metre ground station is planned to be the primary ground facility for communications during all mission phases Expected to arrive in Mercury orbit on 5 December 2025 the Mio and MPO satellites will separate and observe Mercury in collaboration for one year with a possible one year extension 1 The orbiters are equipped with scientific instruments provided by various European countries and Japan The mission will characterize the solid and liquid iron core 3 4 of the planet s radius and determine the size of each 17 The mission will also complete gravitational and magnetic field mappings Russia provided gamma ray and neutron spectrometers to verify the existence of water ice in polar craters that are permanently in shadow from the Sun s rays Mercury is too small and hot for its gravity to retain any significant atmosphere over long periods of time but it has a tenuous surface bounded exosphere 18 containing hydrogen helium oxygen sodium calcium potassium and other trace elements Its exosphere is not stable as atoms are continuously lost and replenished from a variety of sources The mission will study the exosphere composition and dynamics including generation and escape Objectives Edit The main objectives of the mission are 3 19 Study the origin and evolution of a planet close to its parent star Study Mercury s form interior structure geology composition and craters Investigate Mercury s exosphere composition and dynamics including generation and escape Study Mercury s magnetised envelope magnetosphere structure and dynamics Investigate the origin of Mercury s magnetic field Verify Einstein s theory of general relativity by measuring the parameters gamma and beta of the parameterized post Newtonian formalism with high accuracy 20 21 Design Edit Planned orbits for Mio and MPO satellites the two probes of the BepiColombo mission The stacked spacecraft will take seven years to position itself to enter Mercury orbit During this time it will use solar electric propulsion and nine gravity assists flying past the Earth and Moon in April 2020 Venus in 2020 and 2021 and six Mercury flybys between 2021 and 2025 1 The stacked spacecraft left Earth with a hyperbolic excess velocity of 3 475 km s 2 159 mi s Initially the craft was placed in a heliocentric orbit similar to that of Earth After both the spacecraft and Earth completed one and a half orbits it returned to Earth to perform a gravity assist maneuver and is deflected towards Venus Two consecutive Venus flybys reduce the perihelion near to the Sun Mercury distance with almost no need for thrust A sequence of six Mercury flybys will lower the relative velocity to 1 76 km s 1 09 mi s After the fourth Mercury flyby the craft will be in an orbit similar to that of Mercury and will remain in the general vicinity of Mercury see 1 Four final thrust arcs reduce the relative velocity to the point where Mercury will weakly capture the spacecraft on 5 December 2025 into polar orbit Only a small maneuver is needed to bring the craft into an orbit around Mercury with an apocentre of 178 000 km The orbiters then separate and will adjust their orbits using chemical thrusters 22 23 History Edit The BepiColombo mission proposal was selected by ESA in 2000 A request for proposals for the science payload was issued in 2004 24 In 2007 Astrium was selected as the prime contractor and Ariane 5 chosen as the launch vehicle 24 The initial target launch of July 2014 was postponed several times mostly because of delays on the development of the solar electric propulsion system 24 The total cost of the mission was estimated in 2017 as US 2 billion 25 Schedule Edit Animation of BepiColombo s trajectory from 20 October 2018 to 2 November 2025 BepiColombo Earth Venus Mercury Sun For more detailed animation see this video source source source source source source source source source source source source Sequence of images taken during the second Mercury flyby Animation of BepiColombo s trajectory around Mercury As of 2021 update the mission schedule is 1 Date Event Comment20 October 2018 01 45 UTC Launch10 April 2020 04 25 UTC Earth flyby 1 5 years after launch15 October 2020 03 58 UTC First Venus flyby According to Johannes Benkhoff of ESA the probe may possibly be capable of detecting phosphine the chemical allegedly discovered in the Venusian atmosphere in September 2020 during this and the following flyby He stated that we do not know if our instrument is sensitive enough 26 On 15 October 2020 the ESA reported the flyby was a success 27 10 August 2021 13 51 UTC Second Venus flyby 1 35 Venus years after first Venus flyby Flyby was a success and saw BepiColombo come within 552 km of Venus surface 28 29 1 October 2021 23 34 41 UTC First Mercury flyby Passed 199 km from Mercury s surface 30 Occurred on what would have been the 101st birthday of Giuseppe Colombo 23 June 2022 09 44 UTC Second Mercury flyby 2 orbits 3 00 Mercury years after 1st Mercury flyby Closest approach of about 200 km altitude 31 20 June 2023 Third Mercury flyby gt 3 orbits 4 12 Mercury years after 2nd Mercury flyby5 September 2024 Fourth Mercury flyby 4 orbits 5 04 Mercury years after 3rd Mercury flyby2 December 2024 Fifth Mercury flyby 1 orbit 1 00 Mercury year after 4th Mercury flyby9 January 2025 Sixth Mercury flyby 0 43 orbits 0 43 Mercury years after 5th Mercury flyby5 December 2025 Mercury orbit insertion Spacecraft separation 3 75 Mercury years after 6th Mercury flyby14 March 2026 MPO in final science orbit 1 13 Mercury years after orbit insertion1 May 2027 End of nominal mission 5 82 Mercury years after orbit insertion1 May 2028 End of extended mission 9 98 Mercury years after orbit insertion Timeline of BepiColombo from 20 October 2018 to 2 November 2025 Red circle indicates flybys Components EditMercury Transfer Module Edit Earth flyby on 10 April 2020 source source source source source source source source source source source source source source BepiColombo imaged at Northolt Branch Observatories 16 hours after the Earth flyby The bright satellite passing by is INSAT 2D a defunct geostationary satellite QinetiQ T6 Performance 32 33 Type Kaufman Ion EngineUnits on board 4 34 35 Diameter 22 cm 8 7 in Max thrust 145 mN eachSpecific impulse Isp 4300 secondsPropellant XenonTotal power 4628 WThe Mercury Transfer Module MTM is located at the base of the stack Its role is to carry the two science orbiters to Mercury and to support them during the cruise The MTM is equipped with a solar electric propulsion system as the main spacecraft propulsion Its four QinetiQ T6 ion thrusters operate singly or in pairs for a maximum combined thrust of 290 mN 36 making it the most powerful ion engine array ever operated in space The MTM supplies electrical power for the two hibernating orbiters as well as for its solar electric propulsion system thanks to two 14 meter long solar panels 37 Depending on the probe s distance to the Sun the generated power will range between 7 and 14 kW each T6 requiring between 2 5 and 4 5 kW according to the desired thrust level The solar electric propulsion system has typically very high specific impulse and low thrust This leads to a flight profile with months long continuous low thrust braking phases interrupted by planetary gravity assists to gradually reduce the velocity of the spacecraft Moments before Mercury orbit insertion the MTM will be jettisoned from the spacecraft stack 37 After separation from the MTM the MPO will provide Mio all necessary power and data resources until Mio is delivered to its mission orbit separation of Mio from MPO will be accomplished by spin ejection Mercury Planetary Orbiter Edit Mercury Planetary Orbiter in ESTEC before stacking Radio testing of BepiColombo orbiter The Mercury Planetary Orbiter MPO has a mass of 1 150 kg 2 540 lb and uses a single sided solar array capable of providing up to 1000 watts and featuring Optical Solar Reflectors to keep its temperature below 200 C 392 F The solar array requires continuous rotation keeping the Sun at a low incidence angle in order to generate adequate power while at the same time limiting the temperature 37 The MPO will carry a payload of 11 instruments comprising cameras spectrometers IR UV X ray g ray neutron a radiometer a laser altimeter a magnetometer particle analysers a Ka band transponder and an accelerometer The payload components are mounted on the nadir side of the spacecraft to achieve low detector temperatures apart from the MERTIS and PHEBUS spectrometers located directly at the main radiator to provide a better field of view 37 A high temperature resistant 1 0 m 3 ft 3 in diameter high gain antenna is mounted on a short boom on the zenith side of the spacecraft Communications will be on the X band and Ka band with an average bit rate of 50 kbit s and a total data volume of 1550 Gbit year ESA s Cebreros Spain 35 metre ground station is planned to be the primary ground facility for communications during all mission phases 37 Science payload Edit The science payload of the Mercury Planetary Orbiter consists of eleven instruments 38 39 BepiColombo Laser Altimeter BELA developed by DLR in cooperation with the University of Bern the Max Planck Institute for Solar System Research MPS and the Instituto de Astrofisica de Andalucia 40 Italian Spring Accelerometer ISA developed by Italy Mercury Magnetometer MPO MAG MERMAG developed by Germany and United Kingdom 37 Mercury Radiometer and Thermal Infrared Spectrometer MERTIS developed by Germany Mercury Gamma ray and Neutron Spectrometer MGNS developed by Russia Mercury Imaging X ray Spectrometer MIXS developed and built by the University of Leicester the Max Planck Institute for Solar System Research MPS and the Max Planck Institute for extraterrestrial Physics MPE 41 42 Mercury Orbiter Radio science Experiment MORE developed by Italy and the United States Probing of Hermean Exosphere by Ultraviolet Spectroscopy PHEBUS developed by France and Russia Search for Exosphere Refilling and Emitted Neutral Abundances SERENA 43 made up of 2 neutral and 2 ionised particle analysers ELENA Emitted Low Energy Neutral Atoms developed by Italy STROFIO STart from a ROtating Field mass spectrOmeter developed by United States 44 MIPA Miniature Ion Precipitation Analyser developed by Sweden PICAM Planetary Ion CAMera developed by the Space Research Institute Institut fur Weltraumforschung IWF Russian Space Research Institute IKI Institut de recherche en sciences de l environnement CETP IPSL European Space Research and Technology Centre ESTEC Research Institute for Particle and Nuclear Physics KFKI RMKI and the Max Planck Institute for Solar System Research MPS 40 Spectrometers and Imagers for MPO BepiColombo Integrated Observatory System SIMBIO SYS high resolution stereo cameras and a visual and near infrared spectrometer developed by Italy France and Switzerland Solar Intensity X ray and Particle Spectrometer SIXS developed by Finland and United Kingdom Mio Mercury Magnetospheric Orbiter Edit Mio in ESTEC before stacking Mio or the Mercury Magnetospheric Orbiter MMO developed and built mostly by Japan has the shape of a short octagonal prism 180 cm 71 in long from face to face and 90 cm 35 in high 3 45 It has a mass of 285 kg 628 lb including a 45 kg 99 lb scientific payload consisting of 5 instrument groups 4 for plasma and dust measuring run by investigators from Japan and one magnetometer from Austria 3 46 47 Mio will be spin stabilized at 15 rpm with the spin axis perpendicular to the equator of Mercury It will enter a polar orbit at an altitude of 590 11 640 km 370 7 230 mi outside of MPO s orbit 46 The top and bottom of the octagon act as radiators with louvers for active temperature control The sides are covered with solar cells which provide 90 watts Communications with Earth will be through a 0 8 m 2 ft 7 in diameter X band phased array high gain antenna and two medium gain antennas operating in the X band Telemetry will return 160 Gb year about 5 kbit s over the lifetime of the spacecraft which is expected to be greater than one year The reaction and control system is based on cold gas thrusters After its release in Mercury orbit Mio will be operated by Sagamihara Space Operation Center using Usuda Deep Space Center s 64 m 210 ft antenna located in Nagano Japan 38 Science payload Edit Mio carries five groups of science instruments with a total mass of 45 kg 99 lb 3 38 Mercury Plasma Particle Experiment MPPE studies the plasma and neutral particles from the planet its magnetosphere and the solar wind It will employ these instruments Mercury Electron Analyzers MEA1 and MEA2 Mercury Ion Analyzer MIA Mass Spectrum Analyzer MSA developed by Laboratory of Plasma Physics LPP Max Planck Institute for Solar System Research MPS IDA of Technical University of Braunschweig and Institute of Space and Astronautical Science ISAS 48 High Energy Particle instrument for electrons HEP ele High Energy Particle instrument for Ions HEP ion Energetic Neutrals Analyzer ENA Mercury Magnetometer MMO MGF studies Mercury s magnetic field magnetosphere and interplanetary solar wind Plasma Wave Investigation PWI studies the electric field electromagnetic waves and radio waves from the magnetosphere and solar wind Mercury Sodium Atmosphere Spectral Imager MSASI studies the thin sodium atmosphere of Mercury Mercury Dust Monitor MDM studies dust from the planet and interplanetary spaceMercury Surface Element cancelled Edit The Mercury Surface Element MSE was cancelled in 2003 due to budgetary constraints 8 At the time of cancellation MSE was meant to be a small 44 kg 97 lb lander designed to operate for about one week on the surface of Mercury 22 Shaped as a 0 9 m 2 ft 11 in diameter disc it was designed to land at a latitude of 85 near the terminator region Braking manoeuvres would bring the lander to zero velocity at an altitude of 120 m 390 ft at which point the propulsion unit would be ejected airbags inflated and the module would fall to the surface with a maximum impact velocity of 30 m s 98 ft s Scientific data would be stored onboard and relayed via a cross dipole UHF antenna to either the MPO or Mio The MSE would have carried a 7 kg 15 lb payload consisting of an imaging system a descent camera and a surface camera a heat flow and physical properties package an alpha particle X ray spectrometer a magnetometer a seismometer a soil penetrating device mole and a micro rover 49 Artwork EditAs with the Hayabusa2 mission the BepiColombo mission is the topic of artwork The manga artist Masayuki Ishikawa created a piece featuring the character Mercury from the manga Madowanai Hoshi as well as the BepiColombo spacecraft 50 51 See also EditExploration of Mercury MESSENGER the first spacecraft to orbit MercuryReferences Edit a b c d e f g h i BepiColombo Factsheet ESA 6 July 2017 Retrieved 6 July 2017 a b BepiColombo s first image from space ESA 10 October 2018 a b c d e MIO BepiColombo JAXA 2018 Retrieved 9 July 2018 Amos Jonathan 18 January 2008 European probe aims for Mercury BBC News Retrieved 21 January 2008 a b MIO Mercury Magnetospheric Orbiter s New Name Press release JAXA 8 June 2018 Retrieved 9 June 2018 BepiColombo Launch Rescheduled for October 2018 ESA 25 November 2016 Retrieved 14 December 2016 BepiColombo Overview ESA 5 September 2016 Retrieved 13 March 2017 a b Critical Decisions on Cosmic Vision Press release ESA 7 November 2003 No 75 2003 Retrieved 14 December 2016 MPEC 2020 G96 2020 GL2 Minor Planet Center 13 April 2020 Archived from the original on 13 April 2020 2020 GL2 Minor Planet Center 13 April 2020 Archived from the original on 13 April 2020 MPEC 2020 G97 DELETION OF 2020 GL2 Minor Planet Center 13 April 2020 Retrieved 14 April 2020 BepiColombo flies by Earth Europlanet Society 10 April 2020 Retrieved 24 June 2022 The data collected for this image even though it was submitted to the Minor Planet Center as artificial satellite 2018 080A BepiColombo s official designation led to it being mistaken for a Near Earth asteroid The discovery announced by the Minor Planet Center as asteroid 2020 GL2 was retracted soon after This was the third time a spacecraft had been mistakenly announced as a new asteroid during an Earth flyby after Rosetta a k a 2007 VN84 and Gaia a k a 2015 HP116 Incidentally all three of these are ESA missions Hayakawa Hajime Maejima Hironori 2011 BepiColombo Mercury Magnetospheric Orbiter MMO PDF 9th IAA Low Cost Planetary Missions Conference 21 23 June 2011 Laurel Maryland BepiColombo to Enter Implementation Phase ESA 26 February 2007 Amos Jonathan 20 October 2018 Blast off for BepiColombo on mission to Mercury BBC News Retrieved 20 October 2018 Watch BepiColombo launch European Space Agency 16 October 2018 Retrieved 8 December 2021 Science with BepiColombo ESA Accessed 23 October 2018 Domingue Deborah L Koehn Patrick L et al August 2007 Mercury s Atmosphere A Surface Bounded Exosphere Space Science Reviews 131 1 4 161 186 Bibcode 2007SSRv 131 161D doi 10 1007 s11214 007 9260 9 S2CID 121301247 BepiColombo Fact Sheet ESA 1 December 2016 Retrieved 13 December 2016 BepiColombo Testing general relativity ESA 4 July 2003 Archived from the original on 7 February 2014 Retrieved 7 February 2014 Einstein s general relativity reveals new quirk of Mercury s orbit Emily Conover Science News 11 April 2018 a b BepiColombo National Space Science Data Center NASA 26 August 2014 Retrieved 6 April 2015 This article incorporates text from this source which is in the public domain Mission Operations Getting to Mercury ESA Retrieved 7 February 2014 a b c BepiColombo Joint Mission to Mercury Elizabeth Howell Space com 21 October 2018 BepiColombo Mercury mission tested for journey into pizza oven Stephen Clarke Spaceflight Now 17 July 2017 O Callaghan Jonathan In A Complete Fluke A European Spacecraft Is About To Fly Past Venus And Could Look For Signs Of Life Forbes Retrieved 16 September 2020 BepiColombo flies by Venus en route to Mercury ESA 15 October 2020 Retrieved 15 October 2020 The flyby itself was very successful confirms Elsa The only difference to normal cruise phase operations is that near to Venus we have to temporarily close the shutter of any of the star trackers that are expected to be blinded by the planet similar to closing your eyes to avoid looking at the Sun BepiColombo s second Venus flyby in images European Space Agency Retrieved 8 December 2021 Pultarova Tereza 11 August 2021 Mercury bound spacecraft snaps selfie with Venus in close flyby photo Space com Retrieved 8 December 2021 ESA Operations esaoperations 2 October 2021 At 01 34 41 CEST this morning BepiColombo passed just 199 kilometres from the hot rocky innermost planet Tweet via Twitter Second helpings of Mercury European Space Agency 24 June 2022 Retrieved 24 June 2022 Qualification of the T6 Thruster for BepiColombo Archived 12 August 2016 at the Wayback Machine R A Lewis J Perez Luna N Coombs 30th International Symposium on Space Technology and Science 34th International Electric Propulsion Conference and 6th Nano satellite Symposium Hyogo Kobe Japan 4 10 July 2015 QinetiQ s T6 and T5 Ion Thruster Electric Propulsion System Architectures and Performances Mark Hutchins Huw Simpson 30th International Symposium on Space Technology and Science 34th International Electric Propulsion Conference and 6th Nano satellite Symposium Hyogo Kobe Japan 4 10 July 2015 T6 ion thruster firing ESA 27 April 2016 Retrieved 7 August 2019 T6 ion thrusters installed on BepiColombo ESA 26 April 2016 Retrieved 7 August 2019 Clark Stephen D Hutchins Mark S et al 2013 BepiColombo Electric Propulsion Thruster and High Power Electronics Coupling Test Performances 33rd International Electric Propulsion Conference 6 10 October 2013 Washington D C IEPC 2013 133 Archived from the original on 20 December 2016 a b c d e f Mercury Planetary Orbiter Spacecraft ESA 16 August 2018 Retrieved 7 August 2019 a b c MMO Mercury Magnetospheric Orbiter Objectives JAXA 2011 Retrieved 7 February 2014 Mercury Planetary Orbiter Instruments ESA 15 January 2008 Retrieved 6 February 2014 a b MPS BepiColombo SERENA MPS MIXS on BepiColombo Fraser G W Carpenter J D Rothery D A Pearson J F Martindale A Huovelin J Treis J Anand M Anttila M Ashcroft M Benkoff J Bland P Bowyer A Bradley A Bridges J Brown C Bulloch C Bunce E J Christensen U Evans M Fairbend R Feasey M Giannini F Hermann S Hesse M Hilchenbach M Jorden T Joy K Kaipiainen M Kitchingman I Lechner P Lutz G Malkki A Muinonen K Naranen J Portin P Prydderch M Juan J San Sclater E Schyns E Stevenson T J Struder L Syrjasuo M Talboys D Thomas P Whitford C Whitehead S 2010 The mercury imaging X ray spectrometer MIXS on bepicolombo Planetary and Space Science 58 1 2 79 95 Bibcode 2010P amp SS 58 79F doi 10 1016 j pss 2009 05 004 ISSN 0032 0633 SERENA ESA Retrieved 7 August 2019 Strofio Discovery Program NASA Archived from the original on 8 January 2017 Retrieved 7 January 2017 This article incorporates text from this source which is in the public domain Yamakawa Hiroshi Ogawa Hiroyuki et al January 2004 Current status of the BepiColombo MMO spacecraft design Advances in Space Research 33 12 2133 2141 Bibcode 2004AdSpR 33 2133Y doi 10 1016 S0273 1177 03 00437 X a b Mercury Exploration Project BepiColombo PDF JAXA 2014 Retrieved 6 April 2015 A pair of planetary Explorers at Mercury esa int Retrieved 21 October 2018 MPPE BepiColombo s lander ESA 20 February 2002 Retrieved 7 February 2014 石川雅之 27 July 2018 元絵は みお を追加してプロジェクトにご笑納いただきましたpic twitter com fYhYUT7nif isk ms in Japanese Retrieved 9 March 2020 JAXA 惑わない星 水星探査機 みお MIO プロジェクトサイエンティストと石川雅之の打ち上げ直前対談が実現 Google Translate translate google com Retrieved 9 March 2020 External links EditBepiColombo website by the European Space Agency BepiColombo Operations website by the European Space Agency BepiColombo website by JAXA BepiColombo website by JAXA s Institute of Space and Astronautical Science BepiColombo website by NASA s Solar System Exploration BepiColombo website by the National Space Science Data Center The BepiColombo mission to Mercury edited by Johannes Benkhoff Go Murakami and Ayako Matsuoka Space Science Reviews 216 217 2020 2021 BepiColombo article on eoPortal by ESAPortals Astronomy Stars Spaceflight Solar System Retrieved from https en wikipedia org w index php title BepiColombo amp oldid 1130067353, wikipedia, wiki, book, books, library,

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