Dual Segmented Langmuir Probe (DSLP) is an instrument developed primarily by Czech researchers and engineers to study the magnetospheric background plasma flown on board the spacecraft of the European Space Agency (ESA) Proba 2.[1]
Operator | ESA |
---|---|
Manufacturer | Astronomical Institute Institute of Atmospheric Physics, Academy of Sciences of the Czech Republic |
Instrument type | Langmuir probe |
Function | Plasma research |
Website | terezka |
Host spacecraft | |
Spacecraft | Proba-2 |
Operator | ESA |
Launch date | 2 November, 01:50:51 | UTC
Rocket | Rokot/Briz-KM |
Launch site | Plesetsk 133/3 |
COSPAR ID | 2009-059B |
Orbit | Low Earth |
Data acquired by DSLP will be used to reach these specific scientific goals:[2]
- Directional Measurements: Contrary to classical Langmuir probes, the new DSLP concept of data acquisition from the independent segments will enable to study also plasma characteristics in different directions. This should provide for example estimations of plasma flow velocity. Typically in the presence of magnetic field, electron temperatures are observed to be slightly different in the direction parallel and perpendicular to the magnetic field lines. This temperature anisotropy should be measured with DSLP by way of directional data acquisition.
- Non-Maxwellian Features in Ionospheric Plasma: Classical theories for LPs are typically developed for plasmas in a thermodynamic equilibrium, that is for particle populations possessing Maxwellian velocity distribution functions. However, a thermodynamic equilibrium and thus a Maxwellian distribution is an idealized case while the real distribution in many plasma environments often exhibits various non-Maxwellian features, like loss-cone or flat-top distributions or high-energy tails. We intend to adapt the DSLP theoretical model in order to see whether such features exist also in ionospheric plasmas.
- Ionospheric Irregularities: Ionosphere especially in the equatorial region possess several phenomena such equatorial ionization anomaly or ionospheric perturbations in auroral and cusp regions. The latitudinal distribution of these anomalies should be mapped during the whole mission. The effects are also highly dependent on space weather, on magnetospheric forces induced by solar, interplanetary and magnetospheric disturbances. Hence also coordination with LYRA and SWAP (other Proba 2 payload) measurements would be useful to find a correlation between particular solar events and ionospheric disturbances.
- Ionospheric Perturbations by Solar Events (CMEs): This scientific objective will use cooperation with LYRA and SWAP experiments and further more enhance the sphere of interest. Detected solar event, if possible, should start DSLP burst measurement when the solar event affects the Earth.
- Mapping Bulk Plasma Parameters: All acquired DSLP data will be used to map the bulk plasma parameters (primarily electron density and temperature) and to study their latitude and seasonal variations.
The DSLP instrument consists of two Langmuir probes, electronics and small data processing unit. DSLP shares some interface, power and processing resources with TPMU experiment. DSLP has been developed on the basis of its predecessor ISL (Instrument Sonde de Langmuir), flown on the Demeter mission of CNES.
DSLP was developed by the consortium of Astronomical Institute and Institute of Atmospheric Physics, Academy of Sciences of the Czech Republic, Prague, Czech Republic, Research and Scientific Support Department (RSSD) ESA ESTEC, Noordwijk, The Netherlands, Czech Space Research Centre (CSRC), Brno Czech Republic, and SPRINX Systems, Prague, Czech Republic. The team has been led by the Principal Investigator Pavel Trávníček.[3]
References
edit- ^ "The DSLP Langmuir Probe experiment on-board Proba2: scientific objectives and description" (PDF). EGU General Assembly 2009. 11. 2009. Retrieved December 29, 2022.
- ^ "Proba-2 Scientific Instruments - DSLP". ESA. Retrieved December 29, 2022.
- ^ "Development of the Dual Segmented Lagmuir Probe for ESA Proba-1 Satellite". Czech Space Office. September 13, 2010. Retrieved December 29, 2022.