Magnetospheric Multiscale Mission Explained

Magnetospheric Multiscale Mission
Names List:MMS
Mission Type:Magnetosphere research
Operator:NASA
Cospar Id:


Satcat:40482
40483
40484
40485
Website:MMS https://www.nasa.gov/mission_pages/mms/index.html
Mission Duration:Planned: 2 years
Elapsed:
Manufacturer:Goddard Space Flight Center
Dimensions:Stowed:
Deployed:
Power:318 watts
Launch Date:13 March 2015, 02:44 UTC
Launch Rocket:Atlas V 421
AV-053
Launch Site:Cape Canaveral, SLC-41
Launch Contractor:United Launch Alliance
Entered Service:September 2015
Last Contact:2040 (planned)
Orbit Reference:Geocentric orbit
Orbit Regime:Highly elliptical orbit
Orbit Inclination:28.0°
Apsis:gee
Insignia:Magnetospheric Multiscale Mission logo.png
Insignia Size:200px
Programme:Large Strategic Science Missions
Heliophysics Division
Previous Mission:Van Allen Probes
Next Mission:Parker
Programme2:Solar Terrestrial Probes program
Previous Mission2:STEREO
Next Mission2:IMAP

The Magnetospheric Multiscale (MMS) Mission is a NASA robotic space mission to study the Earth's magnetosphere, using four identical spacecraft flying in a tetrahedral formation.[1] The spacecraft were launched on 13 March 2015 at 02:44 UTC.[2] The mission is designed to gather information about the microphysics of magnetic reconnection, energetic particle acceleration, and turbulence⁠ — processes that occur in many astrophysical plasmas.[3] As of March 2020, the MMS spacecraft has enough fuel to remain operational until 2040.[4]

Background

The mission builds upon the successes of the ESA Cluster mission, but will surpass it in spatial resolution and in temporal resolution, allowing for the first time measurements of the critical electron diffusion region, the site where magnetic reconnection occurs. Its orbit is optimized to spend extended periods in locations where reconnection is known to occur: at the dayside magnetopause, the place where the pressure from the solar wind and the planets' magnetic field are equal; and in the magnetotail, which is formed by pressure from the solar wind on a planet's magnetosphere and which can extend great distances away from its originating planet.

Magnetic reconnection in Earth's magnetosphere is one of the mechanisms responsible for the aurora, and it is important to the science of controlled nuclear fusion because it is one mechanism preventing magnetic confinement of the fusion fuel. These mechanisms are studied in outer space by the measurement of motions of matter in stellar atmospheres, like that of the Sun. Magnetic reconnection is a phenomenon in which energy may be efficiently transferred from a magnetic field to the motion of charged particles.[5]

Spacecraft

The MMS mission consists of four spacecraft. Each has a launch mass of . In their stowed launch configuration, each are approximately, and when stacked together they have a total height of . After being deployed in orbit, a total of eight axial and wire booms are deployed, including four Spin-Plane Double Probe (SDP) wire booms each long.

The MMS spacecraft are spin stabilized, turning at a rate of three revolutions per minute to maintain orientation. Each spacecraft contains 12 thrusters connected to four hydrazine fuel tanks. Position data is provided by highly sensitive GPS equipment, while attitude is maintained by four star trackers, two accelerometers, and two Sun sensors.

The mission is broken into three phases. The commissioning phase will last approximately five and a half months after launch, while the science phases will last two years. The first science phase will focus on the magnetic boundary between the Earth and Sun (day side operations) for one and a half years, with the spacecraft formation orbiting the Earth at . The second science phase will study reconnection in Earth's magnetic tail (night side operations) for half a year, increasing the orbit to .

Instruments

Each spacecraft carries several experiments, divided into three suites: the Hot Plasma Suite, the Energetic Particles Detector Suite, and the Fields Suite.[6]

Hot Plasma Suite

The Hot Plasma Suite measures plasma particle counts, directions, and energies during reconnection. It consists of two instruments:

Energetic Particles Detector

The Energetic Particles Detector Suite detects particles at energies far exceeding those detected by the Hot Plasma Suite. It consists of two instruments:

Fields Suite

The Fields Suite[8] measures magnetic and electric field characteristics. It consists of six instruments:

Personnel and development

The principal investigator is James L. Burch of Southwest Research Institute, assisted by an international team of investigators, both instrument leads and theory and modeling experts.[11] The project scientist is Thomas E. Moore of Goddard Space Flight Center.[12] Education and public outreach is a key aspect of the mission, with student activities, data sonification, and planetarium shows being developed.

The mission was selected for support by NASA in 2005. System engineering, spacecraft bus design, integration and testing has been performed by Goddard Space Flight Center in Maryland. Instrumentation is being improved, with extensive experience brought in from other projects, such as the IMAGE, Cluster and Cassini missions. In June 2009, MMS was allowed to proceed to Phase C, having passed a Preliminary Design Review. The mission passed its Critical Design Review in September 2010.[13] The spacecraft launched on an Atlas V 421 launch vehicle,[14] in March 2015.[2] [15]

Formation flying

In order to collect the desired science data, the four satellite MMS constellation must maintain a tetrahedral formation through a defined region of interest in a highly elliptical orbit. The formation is maintained through the use of a high altitude rated GPS receiver, Navigator, to provide orbit knowledge, and regular formation maintenance maneuvers.[16] Through Navigator, the MMS mission broke the Guinness World Record twice for highest altitude fix of a GPS signal (at and above the surface in 2016 and 2019 respectively).[17] [18]

Discoveries

In 2016, the MMS mission was the first to directly detect magnetic reconnection, the phenomenon which drives space weather in the Earth's magnetosphere.[19] [20]

MMS has since detected magnetic reconnection occurring in unexpected places. In 2018, MMS made the first-ever detection of magnetic reconnection in the magnetosheath, a region of space previously thought to be too chaotic and unstable to sustain reconnection.[21] Magnetic flux ropes and Kelvin–Helmholtz vortices are other phenomena where MMS has detected reconnection events against expectations.[4]

In August 2019, astronomers reported that MMS made the first high-resolution measurements of an interplanetary shock wave from the Sun.[22]

See also

References

External links

Notes and References

  1. Web site: MMS Spacecraft & Instruments. NASA. 3 August 2017. 12 March 2020.
  2. Web site: MMS Launch. NASA. 2 April 2015. 12 March 2020.
  3. Web site: MMS-SMART: Quick Facts. Southwest Research Institute. W. S.. Lewis. 5 August 2009. 9 September 2014. https://web.archive.org/web/20140909042225/http://mms.space.swri.edu/quick_facts.html. dead.
  4. Web site: Johnson-Groh. Mara. NASA's MMS Marks its 5th Year Breaking Records in Space . NASA. 12 March 2020. 12 March 2020.
  5. Microphysics of Magnetic Reconnection. Space Science Reviews. Andris. Vaivads. Alessandro. Retinò. Mats. André. 122. 1–4. 19–27. February 2006. 10.1007/s11214-006-7019-3 . 2006SSRv..122...19V. 122892025 .
  6. Web site: Instruments Aboard MMS. NASA. 30 July 2015. 2 January 2016.
  7. Pollock . C. . Moore . T. . Jacques . A. . Burch . J. . Gliese . U. . Saito . Y. . Omoto . T. . Avanov . L. . Barrie . A. . Coffey . V. . Dorelli . J. . Gershman . D. . Giles . B. . Rosnack . T. . Salo . C. . 2016-03-01 . Fast Plasma Investigation for Magnetospheric Multiscale . Space Science Reviews . en . 199 . 1 . 331–406 . 10.1007/s11214-016-0245-4 . 2016SSRv..199..331P . 255065646 . 1572-9672. free .
  8. Torbert . R. B. . Russell . C. T. . Magnes . W. . Ergun . R. E. . Lindqvist . P.-A. . LeContel . O. . Vaith . H. . Macri . J. . Myers . S. . Rau . D. . Needell . J. . King . B. . Granoff . M. . Chutter . M. . Dors . I. . 2016-03-01 . The FIELDS Instrument Suite on MMS: Scientific Objectives, Measurements, and Data Products . Space Science Reviews . en . 199 . 1 . 105–135 . 10.1007/s11214-014-0109-8 . 1572-9672. free .
  9. Lindqvist . P.-A. . Olsson . G. . Torbert . R. B. . King . B. . Granoff . M. . Rau . D. . Needell . G. . Turco . S. . Dors . I. . Beckman . P. . Macri . J. . Frost . C. . Salwen . J. . Eriksson . A. . Åhlén . L. . 2016-03-01 . The Spin-Plane Double Probe Electric Field Instrument for MMS . Space Science Reviews . en . 199 . 1 . 137–165 . 10.1007/s11214-014-0116-9 . 2016SSRv..199..137L . 255069089 . 1572-9672. free .
  10. Ergun . R. E. . Tucker . S. . Westfall . J. . Goodrich . K. A. . Malaspina . D. M. . Summers . D. . Wallace . J. . Karlsson . M. . Mack . J. . Brennan . N. . Pyke . B. . Withnell . P. . Torbert . R. . Macri . J. . Rau . D. . 2016-03-01 . The Axial Double Probe and Fields Signal Processing for the MMS Mission . Space Science Reviews . en . 199 . 1 . 167–188 . 10.1007/s11214-014-0115-x . 2016SSRv..199..167E . 255071960 . 1572-9672. free .
  11. Web site: The SMART Team. Southwest Research Institute. 28 September 2012. 10 October 2008. https://web.archive.org/web/20081010202640/http://mms.space.swri.edu/team.html. dead.
  12. Web site: Q&A: Missions, Meetings, and the Radial Tire Model of the Magnetosphere. NASA . Karen C.. Fox. Tom. Moore. 1 October 2010. 28 September 2012.
  13. News: NASA's Magnetospheric Mission Passes Major Milestone. NASA. Susan. Hendrix. 3 September 2010. 28 September 2012.
  14. United Launch Alliance Atlas V Awarded Four NASA Rocket Launch Missions. United Launch Alliance. 16 March 2009. 5 August 2009. https://web.archive.org/web/20150720000149/http://www.ulalaunch.com/site/pages/News.shtml#/26. 20 July 2015. dead.
  15. News: Spending Lags Growing Recognition of Heliophysics' Contribution. SpaceNews. Debra . Werner. 19 December 2011. 6 March 2014.
  16. Web site: Magnetospheric Multiscale Spacecraft. Goddard Space Flight Center. NASA. 1 May 2018.
  17. Web site: Johnson-Groh. Mara. NASA's MMS Breaks Guinness World Record. NASA . 4 November 2016. 12 March 2020.
  18. Web site: Baird. Danny. Record-Breaking Satellite Advances NASA's Exploration of High-Altitude GPS. NASA. 4 April 2019. 12 March 2020.
  19. Web site: NASA Probes Witness Powerful Magnetic Storms near Earth. Scientific American. Charles Q.. Choi. 13 May 2016. 14 May 2016.
  20. 10.1126/science.aaf2939. 27174677. 2016Sci...352.2939B. Electron-scale measurements of magnetic reconnection in space. Science . 352. 6290. aaf2939. June 2016. Burch. J. L.. Torbert. R. B.. Phan. T. D.. Chen. L.-J.. Moore. T. E. . Ergun. R. E.. Eastwood. J. P.. Gershman. D. J.. Cassak. P. A.. Argall. M. R.. Wang. S.. Hesse. M.. Pollock. C. J.. Giles. B. L.. Nakamura. R.. Mauk. B. H.. Fuselier. S. A.. Russell. C. T.. Strangeway. R. J.. Drake. J. F. . Shay. M. A.. Khotyaintsev. Yu. V.. Lindqvist. P.-A.. Marklund. G.. Wilder. F. D.. Young. D. T.. Torkar. K. . Goldstein. J.. Dorelli. J. C.. Avanov. L. A.. 1. 10044/1/32763. free. free.
  21. Web site: Johnson-Groh. Mara. NASA Spacecraft Discovers New Magnetic Process in Turbulent Space. NASA. 9 May 2018. 12 March 2020.
  22. Web site: NASA's MMS Finds Its 1st Interplanetary Shock. Johnson-Groh. Mara. NASA. 8 August 2019. 12 August 2019.