Swarm (spacecraft)

Swarm

Artist's view of the three Swarm spacecraft
Mission type	Earth's magnetic field observation
Operator	ESA
COSPAR ID	SWARM A: 2013-067B SWARM B: 2013-067A SWARM C: 2013-067C
SATCAT no.	SWARM A: 39452 SWARM B: 39451 SWARM C: 39453
Website	eoPortal - SWARM
Mission duration	4 years (planned) 10 years, 11 months, 12 days (elapsed)
Spacecraft properties
Manufacturer	Astrium
Launch mass	468 kg
Dry mass	369 kg
Dimensions	9.1 m × 1.5 m × 0.85 m
Power	608 watts
Start of mission
Launch date	22 November 2013, 12:02:29 UTC
Rocket	Rokot/Briz-KM
Launch site	Plesetsk, Site 133/3
Contractor	Eurockot
Orbital parameters
Reference system	Geocentric
Regime	Polar orbit
Perigee altitude	SWARM A: ≤460 kilometres (290 mi) SWARM C: ≤460 kilometres (290 mi) SWARM B: ≤530 kilometres (330 mi)
Apogee altitude	SWARM A: ≤460 kilometres (290 mi) SWARM C: ≤460 kilometres (290 mi) SWARM B: ≤530 kilometres (330 mi)
Inclination	SWARM A: 87.4° SWARM C: 87.4° SWARM B: 88.0°
Mean motion	15
Transponders
Band	S Band
Frequency	2 GHz
Bandwidth	6Mbit/s download 4kbit/s upload
Instruments
VFM: Vector Field Magnetometer ASM: Absolute Scalar Magnetometer EFI: Electric Field Instrument ACC: Accelerometer LRR: Laser Range Reflector
Living Planet Programme ← CryoSat-2 ADM-Aeolus →

Swarm is a European Space Agency (ESA) mission to study the Earth's magnetic field. High-precision and high-resolution measurements of the strength, direction and variations of the Earth's magnetic field, complemented by precise navigation, accelerometer and electric field measurements, will provide data for modelling the geomagnetic field and its interaction with other physical aspects of the Earth system. The results offer a view of the inside of the Earth from space, enabling the composition and processes of the interior to be studied in detail and increase our knowledge of atmospheric processes and ocean circulation patterns that affect climate and weather.

Overview

The overall objective of the Swarm mission is to build on the experience from the Ørsted and CHAMP missions and to provide the best ever survey of the geomagnetic field (multi-point measurements) and its temporal evolution, to gain new insights into the Earth system by improving our understanding of the Earth's interior and climate.^[1]

The Swarm constellation consists of three satellites (Alpha, Bravo and Charlie) placed in two different polar orbits, two flying side by side at an altitude of 450 kilometres (280 mi) and a third at an altitude of 530 kilometres (330 mi).^[1][2] The launch was delayed and rescheduled to 12:02:29 UTC on 22 November 2013, from Plesetsk Cosmodrome, Russia.^[3] ESA contracted Astrium to develop and build the three orbiters,^[1] while Eurockot provided the launch services.^[4]

Scientific objectives

Primary objectives:

• Earth core dynamics, geodynamo processes, and core-mantle interaction
• Lithospheric magnetization and its geological interpretation
• 3D electrical conductivity of the mantle
• Currents flowing in the magnetosphere and ionosphere

Secondary objectives:

• Identification of the ocean circulation by its magnetic signature
• Quantification of the magnetic forcing of the upper atmosphere

Payload

The payload of the three spacecraft consists of the following instruments:^[2]

• Vector Field Magnetometer (VFM): Linear and low-noise measurements of the Earth's magnetic field vector components. The fluxgate vector magnetometer is similar to the ones in the satellites Ørsted, CHAMP and SAC-C.
• Absolute Scalar Magnetometer (ASM): Calibration of the main instrument VFM.
• Electric Field Instrument (EFI): Measurement of ion density, drift velocity and electric field.
• Accelerometer (ACC): Measurement of non-gravitational accelerations like air-drag, winds, Earth albedo and solar radiation pressure.
• Laser Range Reflector (LRR): Reflecting quartz prisms as part of the satellite laser ranging network.

Mission history

Pre-launch

The three SWARM satellites arrived at the Plesetsk Cosmodrome in September 2013 to begin final testing before fuelling and incorporation with the Rokot launch vehicle.^[5]

Launch

The SWARM constellation was successfully launched aboard Rokot/Briz-KM on 22 November 2013.^[6]

Operations

The constellation is controlled by the European Space Operations Centre in Darmstadt, Germany. By the beginning of May 2014, SWARM had finished its in-orbit commissioning.^[7] Preliminary data indicates that the constellation is performing well as data received closely matches that from a previous German mission, CHAMP.^[7]

During the commissioning stage problems were discovered with the backup Magnetometer on the "Charlie" satellite, which led to "Bravo" satellite being placed in the lone high altitude orbit (510 km) and "Charlie" joining "Alpha" in the lower tandem orbit (462 km) to improve the resilience of the constellation.^[7] Commissioning data also indicated greater noise in data when a satellite was in view of the sun; the current theory is this is caused by differential heating in the satellite, but this has not been confirmed.^[7] Overall, the constellation is in good health and, due to accurate orbital insertion, has significant fuel reserves remaining.^[7]

Discoveries and applications

In September 2016, scientists published a study that revealed a direct link between GPS blackouts of low-Earth-orbiting satellites and "thunderstorms" in the ionosphere. During the first two years of Swarm's operation their GPS connection was broken 166 times.^[8] The high-resolution observations from the satellite helped to link these outages to ionospheric thunderstorms 300–600 km in the Earth's atmosphere.^[9]

In December 2016, scientists announced that, by using data from the Swarm satellites, they had discovered a new feature in the Earth's outer core, a jet-stream of rapidly moving liquid iron moving at around 50 km per year.^[10][11]

In April 2017, Swarm's data was used to confirm that Steve was a previously unrecognized atmospheric phenomenon.^[12]

In May 2020, Swarm revealed that Earth's magnetic field is gradually weakening in an area stretching from Africa to South America, which might cause technical disturbances in satellites orbiting Earth.^[13]

See also

• ESA's Living Planet Programme
  • GOCE
  • SMOS
  • CryoSat and CryoSat-2
  • ADM-Aeolus
  • EarthCARE
  • BIOMASS
  • FLEX
• Magsat
• Ørsted (satellite)
• Cluster (mission)
• CHAMP (satellite)

References

1. ESA. "SWARM". eoPortal. Retrieved 21 August 2013.
2. SWARM Technical Annex, 2004
3. "Satellites packed like sardines". ESA. 8 November 2013. Retrieved 11 November 2013.
4. Eurockot to launch two ESA Earth observation missions, 9 April 2010
5. "Preparing to Launch SWARM". ESA. 19 September 2013. Archived from the original on 21 September 2013. Retrieved 19 September 2013.
6. Amos, Jonathan (22 November 2013). "Esa's satellite Swarm launch to map Earth's magnetism". BBC News.
7. "Swarm 'delivers on magnetic promise'". BBC. 2 May 2014. Retrieved 2 May 2014.
8. "Swarm reveals why satellites lose track". ESA. 28 October 2016. Retrieved 27 January 2017.
9. "Strange blackouts hits Space satellites near Equator". DTU Space. 30 September 2016. Retrieved 27 January 2017.
10. Amos, Jonathan (19 December 2016). "Iron 'jet stream' detected in Earth's outer core". BBC. Retrieved 8 January 2017.
11. Livermore, Philip W.; Hollerbach, Rainer; Finlay, Christopher C. (19 December 2016). "An accelerating high-latitude jet in Earth's core". Nature. 10: 62–68. Bibcode:2017NatGe..10...62L. doi:10.1038/ngeo2859.
12. McRae, Mike (24 April 2017). "Introducing Steve - a Newly Discovered Astronomical Phenomenon". ScienceAlert.
13. "Swarm probes weakening of Earth's magnetic field". ESA. 20 May 2020.

External links

• ESA web page on the mission
• eoPortal page of SWARM