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Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Coronal Mass Ejections (CME) S. K. Antiochos,

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Presentation on theme: "Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Coronal Mass Ejections (CME) S. K. Antiochos,"— Presentation transcript:

1 Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Coronal Mass Ejections (CME) S. K. Antiochos, NASA/GSFC

2 Observations –Morphology –Quantitative properties Underlying Physics –Aly-Sturrock limit Present Theories/Models Rules of the Lecture Road –Tailgate! –Backseat Drive! Coronal Mass Ejections (CME) S. K. Antiochos, NASA/GSFC

3 LASCO C3 Observations of Outer Corona

4 Coronagraph: 5 – 30 R_s FOV, Cadence ~ 1 hour Thomson scattering of photospheric white light –I ~ ∫ n_e dl Observe solar wind structures –V ~ 400 km/s ~ 3 CMEs/day –Some with V > 1,000 km/s –C_s ~ 10 4.2 T 1/2 ~ 100km/s –V_A ~ 10 11.3 B n -1/2 ~ 100km/s –Therefore, must have IP shock –Produces large SEP event, (Jokipii) Need to see coronal origins

5 Solar Origins of CMEs Event directly toward or away from Earth appears as halo Observe dense structure embedded in ejection

6 Solar Origins of CMEs

7 SOHO EIT (EUV telescope), –Observe Fe XII 195A line formed at T ~ 1.5 MK –I ~ ∫ n_e n_i G(T) dl –NOTE!! Bright means high density at a particular T; Dark does not mean lack of material –Cadence ~ 12 min –Resolution ~ 1,500 km Ejection of filament and formation of bright flare loops associated with CME –Filament ejection much faster than coronal evolution –All CMEs/flares associated with a filament channel

8 Filament Properties Always lie above photospheric polarity inversion line Fairly common, ~ 50 % coverage, both active & quiet Origin is one of the outstanding problems in solar physics 10/02/00 observations by EIT/SOHO and Kitt Peak

9 Filament Ejection and Flare

10 Solar Origins of CMEs TRACE (EUV telescope) observations of 06/16/2005 event –Observe Fe XIX 171A line formed at T ~ 1.0 MK –Very high cadence < 1 m, and resolution ~ 700 km Cool (<.01 MK) dense prominence/filament lying below coronal loops (seen in absorption) –Loop height ~ 50 Mm, filament height < 5 Mm –But note, grav. scale height H_g ~ 10 3.7 T cm –Loop plasma supported by its internal pressure, but prominence plasma must be supported by magnetic field –Field must be horizontal (or concave up) in filament Coronal loops open and reform during ejection –Clearly, magnetically driven

11 Recap of CME Morphology “Typical” event consists of 3 components: –Ejection of coronal magnetic field and mass –Ejection of filament/prominence field and mass –Heating of > 10MK flare coronal loops and acceleration of flare particles (Krucker) Strength of each component can vary between events, but all are present to some degree –How are they related? What is role of photosphere?

12 Role of Photosphere

13 Filament overlies polarity inversion line (PIL) – low lying Filament field strongly non-potential (large free energy) – Only place in corona where field observed to have high stress! Photospheric B-field does not evolve during eruption Energy buildup slow compared to eruption – 1 km/s Relation of CME Components: Filament rises before onset of flare heating – Timing wrt CME onset not clear

14 For large event: M ~ 10 16 gm, V ~ 1,000 km –E ~ 10 32 ergs, t ~ 10 3 s, Power ~ 10 29 ergs/s –L ~ 10 10 cm, W ~ 10 9 cm, F ~ 10 10 ergs/cm 2 /s –Poynting flux ~ E B V, if B ~ 10 3 G, V ~ 10.5 km/s – much larger than photospheric V A –note that F ~ 10 3 active region heating – also much larger than chromospheric heating Plasma plays negligible role in energetics –active region: T ~ 10 6.5 K, N ~ 10 10.5 /cm 3, E G ~ 10 ergs/cm 3 – B ~ 10 2.5 G, E B ~ 10 3.5 ergs/cm 3 –also gravitational potential energy, M g sun H ~ E G << E B CME Quantitative Properties

15 CME/eruptive flare due to explosive release of magnetic energy stored in corona For some reason, both low-lying filament channel field and overlying coronal field lose equilibrium and expand outward at Alfvenic speeds Closing and relaxation of opening field lines produces flare heating and particle acceleration Rapid drop-off of V A with height produces IP shock, V ~ r -3 Basic CME Scenario

16 Basic CME Cartoon + - (Courtesy, T. Forbes)

17 Closest terrestrial analogy is volcano –Disruption of force balance between upward push and downward pull –Fast removal of downward pull results in supersonic expansion On the Sun, this must all be done with smoke and magnetism –Filament channel field provides upward push and free energy –Overlying coronal field provides downward pull –But field lines cannot break!! Underlying CME Physics

18 Consider Lorentz force of filament channel and overlying field: J x B = (  x B) x B = -  (B 2 /2) + (B·  ) B = -  ┴ (B 2 /2) + B 2 (i B ·  ) i B magnetic pressure magnetic tension Pre-CME Force Balance Dipole field Force-free sheared dipole

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