Prospects for European Space Weather Measurements

1. Prospects for European Space Weather Measurements Volker Bothmer Institute for Astrophysikcs, University Göttingen, Germany Third Space Weather Week, 13-17 November 2006, Brussels, Belgium

2. Definition of Space Weather Measurements In this presentation Space Mission are primarily taken into account in the timeframe 2006 until beyond 2010 if they involve European Participation and if the Instrumentations provide measurements that will further our insights about the physics of the complex Sun-Earth System - i.e. the Sun, inner heliosphere, Earth‘s magnetosphere, ionosphere and lower atmospheric layers - either through newly developed devices or through monitoring strategies. However, because of the variety of individual missions, it must not necessarily be overall complete. Mission Overview provided by G. Withbroe for ILWS. Planetary Missions (e.g., Bepi Colombo) not included. 4,5 3 2 1

3. Part I a) Ongoing Solar Missions

4. Overview Solar Missions

5. Part I b) New Solar Missions

6. Overview New Solar Missions • ASPIICS, Twin satellite system - formation flight, LEO, inner corona and CMEs in EUV white-light, Lyman alpha, science firsts, under study for ESA Proba 3 • (Chandraayana-1, Polar lunar orbit, X-ray imaging, 2007-2008, 2 yrs, Indian Space Agency) • CORONAS-Photon, LEO, EUV, gammas, hard and soft X-rays, energetic particles, launch planned for 2007, RUS • EarthShine, L1, Sun eneregy output and Earth‘s atmosphere, UK, under study by RAL • KuaFu, L1 and B1, B2 in polar orbits, Sun-Earth-System, NSF China, under study • L5 mission, L5, Stereotype mission, in-situ and remote sensing, NICT/CRL (Japan), next solar max • Lyot/Mirages, LEO, solar corona, remote sensing incl. FIR, CNES, after 2012 • Picard, sun-sync. LEO, Irradiance, CNES, 2008 • Proba 2, LEO sun-sync., high-res. EUV and irradiance, ESA (Russian launcher), 2007 • SDO, incl. geosync., high-res. remote sensing, helioseismology, irradiance, EUV but NO CORONAGRAPH, NASA, 2008 • SMESE, CSSAR, LEO, flares and CMEs, China, 2009-2010 • SolACES, ISS, irradiation monitor for UV and EUV, Shuttle launch, DLR, NASA, 2007 • SOLSPEC, ISS, solar spectrometer in the UV, visible, IR, irradiance, Shuttle launch, IASB, ESA, NASA, 2007

7. Overview New Solar Missions • SOVIM, inner heliospheric with high incl., in-situ near Sun package, RMI Belgium, ESA, to be developed • Solar Probe, polar heliocentric, coronal encounter, in-situ and remote sensing package, NASA, 2013 • SPORT, solar orbit with high incl., mother sat. plus 8 tethered children, in-situ and remote sensing, CME and plasma tracking, Chinese Academy of Sciences, under study • SST, sun-sync. 800 km, remote sensing, X/γ-rays, radio, solar magnetic field, flares, CNSA (China), 2008 • Sunrise, balloon flight, high-res. magnetic fields at the Sun, MPS, Germany, 2008

8. Overview Inner Heliospheric Missions

9. Part II b) New Inner Heliospheric Missions

10. Overview New Inner Heliospheric Missions • Geostorm, L1, solar wind, NOAA, under study • Interhelioprobe, heliocentric, perihel inside Mercury orbit, in-situ and remote sensing, IZMIRAN, IKI, NPO (RUS), 2007-2008 • Plasma-F, 7-8 days out of 9 in ip medium, Package on SPECTR-R satellite, IKI (Hungary), 2007 • Sentinels, multiple spacecraft in heliocentric orbits, in-siut packages, NASA, 2015

11. Part III a) Ongoing Magnetospheric Missions

12. Overview Magnetospheric Missions

13. Part III b) New Magnetospheric Missions

14. Overview New Magnetospheric Missions • GEC, four satellites in changing orbit, geospace electrodynamics, NASA, 2013 • Interball-PROGNOZ, multiple sat system, 1 Sat in outer magnetosphere and tail, 3 ionospheric satelllites, IKI, NPO (Russia), Brazil and other countries, 2008 • Maxwell/APEX, twin geostationary system, magnetospheric physics, UK, proposed as ESA Flexi • MMS, 4 satellites in magnetospheric orbits, magnetospheric processes, N ASA, 2013 • M3, Multi-spacecraft mission in Magnetosphere, magnetospheric processes, ESA, 2015-2025 • Orbitals, multiple satellites in magnetosphere, radiation belts, CSA (Canada), 2012 • Radiation Belt Storm Probes, twin system in elliptical near eq. orbits, characteristics of magnetosphere, NASA, 2011 • Resonance, 2 spacecraft in special magnetospheric orbits, inner magnetosphere, IKI, IPF (RUS), under study • ROY, 4 plus 1 spacecraft in polar orbit, magnetospheric scales, RASA (RUS), under study • SCOPE, 4 plus 1 spacecraft in magnetotail, magnetotail, ISAS, 2012 • STORMS, eq. orbits, inner magnetospheric studies, Finland, under study, 2007 • SWARM, 4 sat. in 2 polar orbits, geomagnetic field survey, ESA, 2009 • SWISE, 3 sat. in magnetosphere, response of geospace to solar and interplanetary conditions, CNSA (China), 2020 • THEMIS, 3 inner magnetospheric probes, magnetospheric substorms, NASA, 2006 • TWINS, 2 high incl. sat., multi-scale magnetospheric processes, NASA, 2006/2007

15. Part IV a) Ongoing Ionospheric/Atmospheric Missions

16. Overview Ionospheric/Atmospheric Missions

17. Part IV b) New Ionospheric/Atmospheric Missions

18. New Ionospheric/Atmospheric Missions • AIM (Aeronomy of ICE in the Mesosphere), NASA, Polar Mesospheric Clouds, LEO sun-sync., launch 2006? • CINDI/CNOFS, LEO, F-region characteristics, NASA, DoD, launch planned for 2006 • EarthShine, L1, Sun eneregy output and Earth‘s atmosphere, UK, under study by RAL • Environment, LEO, microsatellite Chibis, EM ionosphere, RUS and other Eastern European Countries, launch planned for 2006 • EPOP, LEO, ionospheric conditions, CSA (Canada), launch planned for 2006 • EQUARS, LEO, atmospheric coupling, INPE (Brazil), launch planned for 2006 • FUV Imager, LEO high lat., ionosphere and thermosphere, NASA, 2012 • Heracles, LEO, microsats, geospace environment, France, under study • Ionosphere/Thermosphere Probes, twin spacecraft, inclined LEO, mid-latitude ionosphere, NASA, 2015 • TARANIS, LEO, atmospheric, magnetospheric, ionospheric couplings, CNES (France), 2009

19. Part V Conclusions

20. Conclusions (of the presenter!) • The variety of missions in operation and under study made it almost impossible to clearly identify the missions WIHOUT European participation –being prominent in mission developments, science and instrumentation! (I found it not adequate to advertise individual projects). • This clearly documents our high level of excellence in space science with regard to the field of space weather! • However, there appears a general lack of L1 solar wind monitoring missions! • Despite the large number of missions, no clear focussed space weather mission covering major space weather issues of the major fields of the SE-systems exists so far!

21. Conclusions (of the presenter!) • It appears to me today as one of the most important task for the community to define an integrated (covering the major issues of space weather), concept for a space weather mission, preferentially in LEO (optimization of technical and cost reasons compared to L1 missions). This could be achieved probably fastest through national activities or a network combining these efforts (ESA). • This task is urgent with respect to the upcoming solar maximum in a couple of years and our invention of the Galileo system, also with respect to the fast path some nations already go.

22. Special Thanks to the People who helped to built EIT!