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The Space Environment II: Characteristics of the Plasma and Radiation Environments

The Space Environment II: Characteristics of the Plasma and Radiation Environments. Dr. Andrew Ketsdever MAE 5595 Lesson 5. Plasma Environment. Magnetosphere Geomagnetic field around Earth Interacts with solar wind Deflects most of the plasma flow Ring Current

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The Space Environment II: Characteristics of the Plasma and Radiation Environments

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  1. The Space Environment II: Characteristics of the Plasma and Radiation Environments Dr. Andrew Ketsdever MAE 5595 Lesson 5

  2. Plasma Environment • Magnetosphere • Geomagnetic field around Earth • Interacts with solar wind • Deflects most of the plasma flow • Ring Current • Encircles magnetic equator (3-6 RE) • Formed by the drift of charged particles • Ions (+) move westward • Electrons (-) move eastward • Energies from 10 to 250 keV (85 keV average) • Plasma Sheet • Current system which separates oppositely directed magnetic fields emanating from N and S poles • Energies • Electrons: 0.5 to 1.0 keV • Ions: 2 to 5 keV

  3. Plasma Environment

  4. Ionosphere • Charge neutrality exists above the D Layer • Ions and electrons are almost always created or destroyed in pairs • Some regions (eg. F1) disappear completely after local sunset • Regions are described by radio frequencies (highest frequency reflected by the layer)

  5. Ionosphere

  6. Plasma Environment

  7. Plasma Interactions • Electron and Ion interactions with surfaces • Augering • Desorption of inner core electrons • Sputtering • Removal of material from surface • Penetration • Absorption at a depth from the surface • Secondary electron emission • Removal of electrons from surface • EM emission • Emission of highly energetic (x-ray) photons

  8. Secondary Electron Yield

  9. Secondary Electron Yield

  10. Secondary Electron Emission

  11. Secondary Electron Emission

  12. Plasma Interactions

  13. LEO Plasma Environment • Quasi-neutral plasma • At 300 km, n ~ 105 cm-3 • Te,i ~ 1000 K (quasi-equilibrium) • Je ~ 1 mA/m2 • Photoemission ~ 10 A/m2 • Secondary electron emission ~ 0.01 Je • Sputtering yield is negligible • LEO major source is incident ambient plasma • Enhancement of plasma environment at high inclinations (auroral zones) • High density • High energy (several keV)

  14. GEO Plasma Environment • Plasma is not quasi-neutral • At GEO, n ~ 1 cm-3 • Energies • Ions: 10 keV (H+) • Electrons 2.4 keV • Je ~ 10 nA/m2 • Photoemission ~ 10 A/m2 • Secondary electron emission and sputtering yield are not negligible • Enhanced by solar storms / events

  15. Spacecraft Charging

  16. Unbiased Spacecraft Charging in LEO

  17. Unbiased Spacecraft Charging in LEO

  18. Biased Spacecraft Charging

  19. Biased Spacecraft Charging

  20. GEO Charging

  21. GEO Charging: SEU SCATHA Data

  22. SCATHA • Launched 31 JAN 1975 to study effects of high altitude charging • Perigee: 5.3 RE • Apogee: 7.8 RE • GEO: 6.6 RE • Inclination: 8º • Period: 23.6 hours • Drift around Earth every 70 days

  23. SCATHA Data

  24. SCATHA Data

  25. SCATHA Data

  26. Radiation Environment: GCR

  27. Radiation Environment: Solar

  28. Radiation Environment: Solar

  29. Radiation Environment: Trapped

  30. Radiation Environment: Van Allen Radiation Belts

  31. Radiation Environment: Van Allen Radiation Belts 1e7 5e6 Solar Max Solar Min

  32. Radiation Environment: Van Allen Radiation Belts

  33. Earth Radiation Environment

  34. Radiation Terminology • RAD: Radiation absorbed dose • 1 rad = 0.01 J/kg (about the energy to lift a paper clip 1 mm off a table) • RBE: Relative biological effectiveness • Represents destructive power of dose on living tissue • REM: Roentgen equivalent mean • Product of RAD and RBE • Cumulative over the lifetime of the subject

  35. Radiation Effects • Effects of radiation dosage on humans • Blood count changes (15-50 REM) • Vomiting (100 REM) • Mortality (150 REM) • Leathal Dosage 50% of population (320-360 REM) • Common event dosage • Transcontinental roundtrip (0.004 REM) • Chest X-ray (0.01 REM) • Living in Los Angeles (0.1 REM) • Living in Denver (0.2 REM) • Space Shuttle Mission (0.65 REM) • Skylab 3 for 84 days (17.85 REM)

  36. Radiation Interactions

  37. Radiation Interactions • Permanent radiation effects • Change in material that persists after material removed from radiation source • Typically caused by atomic displacements in the material • Transient radiation effects • Change in material does not persist after material removed from radiation source • Alters material properties during exposure

  38. Radiation Interactions: Photons • Photoelectric effect: Incident photon imparts energy to material electron • Compton scattering: Photon loses part of its energy to electron, remaining energy is released in lower energy photon • Pair production: Photon materializes into an electron-positron pair

  39. Current Photon Radiation Environment

  40. Radiation Effects: Electrons

  41. Radiation Interaction: Ions

  42. Radiation Interactions

  43. Radiation Shielding Low Z material is better.

  44. Radiation Shielding

  45. Radiation Effects • Degradation • Human • Optical Surfaces • Solar Arrays • Thermal Properties • Mechanical Properties • Sensors and Processors • False readings • SEU • Latch ups Solar proton event 11/1997

  46. 1989 Solar Event

  47. Historical Solar Events

  48. Solar Array Degradation

  49. Stardust Mission • Stardust Craft Tested for Damage After Solar Storm By Lee SiegelScience Writerposted: 07:05 pm ET08 August 2000Originally posted 4:45 p.m., 8/8/00  • A test performed Tuesday August 8 ruled out fears that solar flares damaged the camera on the Stardust spacecraft, which is due to photograph Comet Wild 2 and collect collect comet dust in 2004. Now engineers will try to fix another problem that threatens to degrade Stardusts comet pictures. • "The flares didnt do a thing to us," said Ray Newburn, who heads the Stardust imaging team at NASAs Jet Propulsion Laboratory in Pasadena, Calif. • NASA earlier had feared possible solar radiation damage to the NAVCAM camera s electronic sensor. The agency had said the July solar flares might increase background "noise" that could "mask" Stardusts images of dim stars and Comet Wild 2. • Engineers tested the camera by turning on the electronic sensor -- known as a CCD or charge couple device -- without opening the shutter. A test image showing a known uniform shade of gray would indicate there was no damage, while brighter gray would indicate there was damage, said Tom Duxbury, • Stardusts acting project manager. Newburn said the lack of solar radiation damage means engineers now will proceed with a two-week effort to use the cameras heater to burn off contaminants coating the sensor. That repair was delayed while engineers first checked for radiation damage.

  50. Effects of the Plasma and Radiation Environments

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