Presentation is loading. Please wait.

Presentation is loading. Please wait.

GLOBAL ENERGETICS OF FLARES Gordon Emslie (for a large group of people)

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "GLOBAL ENERGETICS OF FLARES Gordon Emslie (for a large group of people)"— Presentation transcript:

1 GLOBAL ENERGETICS OF FLARES Gordon Emslie (for a large group of people)

2 Initial Study (Emslie et al. 2004) ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB Flare ThermalU th ElectronsUeUe IonsUi CME KineticUKUK PotentialUU SEPsUPUP

3 Methodologies Magnetic Energy U B =

4 Methodologies Thermal Plasma U th = 3 n e V kT = 3 k T [EM. V] 1/2 erg Emission measure (EM) and temperature (T) obtained from both RHESSI and GOES soft X-ray observations. Source volumes (V) were obtained from RHESSI 12 – 25 keV images using V = f V apparent = f A 3/2 where f is the filling factor (assumed to be 1) and A is the area inside the contour at 50% of the peak value.

5 Figure 1. RHESSI image at the impulsive peak of the 2 Nov. 2003 flare. Contours: blue: 12 – 25 keV (50%), magenta: 50 – 100 keV (30 & 70%)

6 Methodologies CME U K = ½ Mv 2 U  = -GM  M/R M determined from scattered brightness V determined from rate of change of position R

7 Methodologies Electrons U E = A   E 0 F 0 (E 0 ) dE 0 dt F 0 (E 0 ) determined from collisional thick target interpretation of HXR spectrum Depends on lower energy “cutoff” E C

8 The Electron “Problem” Efficiency of bremsstrahlung production ~ 10 -5 (ergs of X-rays per erg of electrons)  Electron flux ~ 10 5  hard X-ray flux Electron energy can be 10 32 – 10 33 ergs in large events Total number of accelerated electrons up to 10 40 (cf. number of electrons in loop ~10 38 ). –replenishment and current closure necessary

9 Electrical Current Issue Rate of e - acceleration in large flares  10 37 s -1 Associated Current  10 37 e - s -1  10 18 A Width of Channel ~ 10 7 m –Ampère law  B =  o I/2  r ~ 10 4 T = 10 8 G –Faraday law  V = L dI/dt ~ (  o ) I/  ~ 10 19 V These are impossibly large: –e.g.,  (B 2 /8  ) dV ~ 10 42 ergs Dynamic pressure ~ (nv)(mv) –~ 10 dyne cm -2 (cf. 2nkT ~ 10 dyne cm -2 )

10 Resolution? – Multiple Channels Current density j ~ 10 4 A m -2 Maximum radius of current channel from (Ampère)  B ~ B/r =  o j  r = B/  o j ~ 10 m (Faraday) V=  o L(  r 2 j)/   r ~ 1 m (!)  Number of channels ~ 10 12 (10 14 ) Operating simultaneously!?

11

12 Methodologies Ions U i = A   E 0 F 0 (E 0 ) dE 0 dt AF 0 (E 0 )  dt determined from fit to gamma-ray observations Also depends on lower energy “cutoff” E C (~ 1 MeV?) Electrical current issues not as large Impulse-momentum issues much more important - dynamic pressure ~ (nv)(mv) –100 dyne cm -2 (cf. 2nkT ~ 10 dyne cm -2 )

13 Electron vs. Ion Acceleration gives equality of ion acceleration and escape times E D ~ 10 -8 n(cm -3 )/T(K) V cm -1 ~ 10 -4 V cm -1  maximum electron energy ~ 1 MeV??

14 Methodologies SEPs U P determined from direct observations of SEP fluences at 1 AU Assumptions: –solid-angle extent –number of particles crossings

15 Results (Emslie et al. 2004) ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB Flare ThermalU th ElectronsUeUe IonsUi CME KineticUKUK PotentialUU SEPsUPUP

16 Results (Emslie et al. 2004) ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB 32.3 ± 0.3 Flare ThermalU th 31.3 (+0.4,-1)31.1 (+0.4,-1) ElectronsUeUe 31.3 (+?, -0.5)31.5 (+?, -0.5) IonsUi< 31.631.9 ± 0.5 CME KineticUKUK 32.3 ± 0.332.0 ± 0.3 PotentialUU 30.7 ± 0.331.1 ± 0.3 SEPsUPUP 31.5 ± 0.6< 30

17 July 23, 2002 Summary

18 Refinement (Emslie, Dennis, Holman, Hudson 2005) Include Optical/EUV Continuum Recognize Primary Intermediate Final modes of energy

19 Refinement (Emslie, Dennis, Holman, Hudson 2005) Include Optical/EUV Continuum Recognize Primary Magnetic Field Intermediate Final modes of energy

20 Refinement (Emslie, Dennis, Holman, Hudson 2005) Include Optical/EUV Continuum Recognize Primary Magnetic Field Intermediate Electrons, Ions Final modes of energy

21 Refinement (Emslie, Dennis, Holman, Hudson 2005) Include Optical/EUV Continuum Recognize Primary Magnetic Field Intermediate Electrons, Ions Final Kinetic Energy, Radiation modes of energy

22 Revised Numbers ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB 32.3 ± 0.3 Flare Intermediate ThermalU th 31.3 (+0.4,-1)31.1 (+0.4,-1) ElectronsUeUe 31.3 (+?, -0.5)31.5 (+?, -0.5) IonsUi< 31.631.9 ± 0.5 Final SXR RadiationURUR 31.331.0 Total RadiationURUR > 31.7> 31.6 CME KineticUKUK 32.3 ± 0.332.0 ± 0.3 PotentialUU 30.7 ± 0.331.1 ± 0.3 SEPsUPUP 31.5 ± 0.6< 30

23 Revised Numbers ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB 32.3 ± 0.3 Flare Intermediate ThermalU th 31.3 31.3 (+0.4,-1)31.1 (+0.4,-1) ElectronsUeUe 31.3 31.3 (+?, -0.5)31.5 (+?, -0.5) IonsUi< 31.631.9 ± 0.5 Final SXR RadiationURUR31.331.0 Total RadiationURUR > 31.7> 31.6 CME KineticUKUK 32.3 ± 0.332.0 ± 0.3 PotentialUU 30.7 ± 0.331.1 ± 0.3 SEPsUPUP 31.5 ± 0.6< 30

24 Revised Numbers ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB 32.3 32.3 ± 0.332.3 ± 0.3 Flare Intermediate ThermalU th 31.3 (+0.4,-1)31.1 (+0.4,-1) ElectronsUeUe 31.3 (+?, -0.5)31.5 (+?, -0.5) IonsUi< 31.631.9 ± 0.5 Final SXR RadiationURUR 31.331.0 Total RadiationURUR > 31.7 > 31.6 CME KineticUKUK 32.3 32.3 ± 0.332.0 ± 0.3 PotentialUU 30.7 ± 0.331.1 ± 0.3 SEPsUPUP 31.5 ± 0.6< 30

25 Revised Numbers ModeSymbolLog (Energy) April 21, 2002July 23, 2002 MagneticUBUB 32.3 ± 0.3 Flare Intermediate ThermalU th 31.3 (+0.4,-1)31.1 (+0.4,-1) ElectronsUeUe 31.3 (+?, -0.5)31.5 (+?, -0.5) IonsUi< 31.631.9 ± 0.5 Final SXR RadiationURUR 31.331.0 Total RadiationURUR > 31.7> 31.6 CME KineticUKUK 32.3 32.3 ± 0.332.0 ± 0.3 PotentialUU 30.7 ± 0.331.1 ± 0.3 SEPsUPUP 31.5 31.5 ± 0.6< 30

26 Conclusion CME energy still dominant by factor of ~4BUT Within uncertainties, rough equipartition amongst –Flare intermediate –Flare final –CME SEP shock acceleration <~ 10% efficient

27 Extension to Oct/Nov 2003 Flares (RHESSI/SOHO/TRACE group) Thermal and CME energetics by B. Dennis et al., N. Gopalswamy Electron/ion energetics to follow

28 Figure 5.

29

30

31

32

33

34

35 Figure 6. Flare Energies vs. U peak

36 Conclusions Flare and CME energies are correlated for the Oct/Nov 2003 period. Total Flare and CME energies are comparable to within a factor of 10. Peak energy in SXR-emitting plasma is only ~1% of total flare energy in some cases. Energy radiated by SXR-emitting plasma is only ~10% of total flare energy in some cases. Energy in nonthermal electrons and ions can be a large fraction of the total flare energy. Dominant flare energy in impulsive phase may be electrons and/or ions leading to early peak in total solar irradiance increase seen with SORCE/TIM.

Download ppt "GLOBAL ENERGETICS OF FLARES Gordon Emslie (for a large group of people)"

Similar presentations

RHESSI Investigations of the Neupert Effect in Solar Flares Brian R. Dennis AAS/SPD Meeting 6 June 2002.

RHESSI Investigations of the Neupert Effect in Solar Flares Brian R. Dennis AAS/SPD Meeting 6 June 2002.
Masuda Flare: Remaining Problems on the Looptop Impulsive Hard X-ray Source in Solar Flares Satoshi Masuda (STEL, Nagoya Univ.)

Masuda Flare: Remaining Problems on the Looptop Impulsive Hard X-ray Source in Solar Flares Satoshi Masuda (STEL, Nagoya Univ.)
RHESSI observations of LDE flares – extremely long persisting HXR sources Mrozek, T., Kołomański, S., Bąk-Stęślicka, U. Astronomical Institute University.

RHESSI observations of LDE flares – extremely long persisting HXR sources Mrozek, T., Kołomański, S., Bąk-Stęślicka, U. Astronomical Institute University.
Thick Target Coronal HXR Sources Astrid M. Veronig Institute of Physics/IGAM, University of Graz, Austria.

Thick Target Coronal HXR Sources Astrid M. Veronig Institute of Physics/IGAM, University of Graz, Austria.
Solar Physics with X-ray Observations Gordon D. Holman Solar Physics Laboratory (Code 671) NASA Goddard Space Flight Center RHESSI Fermi Gamma-ray Burst.

Solar Physics with X-ray Observations Gordon D. Holman Solar Physics Laboratory (Code 671) NASA Goddard Space Flight Center RHESSI Fermi Gamma-ray Burst.
Energy Release and Particle Acceleration in Solar Flares Nicole Vilmer LESIA-Observatoire de Paris VII COLAGE-Atibaia 01/04/04.

Energy Release and Particle Acceleration in Solar Flares Nicole Vilmer LESIA-Observatoire de Paris VII COLAGE-Atibaia 01/04/04.
Energy Release and Particle Acceleration in Flares Siming Liu University of Glasgow 9 th RHESSI Workshop, Genova, Italy, Sep. 2009.

Energy Release and Particle Acceleration in Flares Siming Liu University of Glasgow 9 th RHESSI Workshop, Genova, Italy, Sep
R. P. Lin Physics Dept & Space Sciences Laboratory University of California, Berkeley The Solar System: A Laboratory for the Study of the Physics of Particle.

R. P. Lin Physics Dept & Space Sciences Laboratory University of California, Berkeley The Solar System: A Laboratory for the Study of the Physics of Particle.
Solar flares and accelerated particles

Solar flares and accelerated particles
Particle Acceleration in Solar Energetic Particle (SEP) Events and Solar Flares R. P. Lin Physics Department & Space Sciences Laboratory University of.

Particle Acceleration in Solar Energetic Particle (SEP) Events and Solar Flares R. P. Lin Physics Department & Space Sciences Laboratory University of.
M1.0 flare of 22 Oct 2002 RHESSI observations of the M 1.0 solar flare on 22 October 2002 A. Berlicki 1,2, B. Schmieder 1, N. Vilmer 1, G. Aulanier 1 1)

M1.0 flare of 22 Oct 2002 RHESSI observations of the M 1.0 solar flare on 22 October 2002 A. Berlicki 1,2, B. Schmieder 1, N. Vilmer 1, G. Aulanier 1 1)
Low-Energy Coronal Sources Observed with RHESSI Linhui Sui (CUA / NASA GSFC)

Low-Energy Coronal Sources Observed with RHESSI Linhui Sui (CUA / NASA GSFC)
Hard X-Ray Footpoint Motion in Spectrally Distinct Solar Flares Casey Donoven Mentor Angela Des Jardins 2011 Solar REU.

Hard X-Ray Footpoint Motion in Spectrally Distinct Solar Flares Casey Donoven Mentor Angela Des Jardins 2011 Solar REU.
Super-Hot Thermal Plasmas in Solar Flares

Super-Hot Thermal Plasmas in Solar Flares
Relations between concurrent hard X-ray sources in solar flares M. Battaglia and A. O. Benz Presented by Jeongwoo Lee NJIT/CSTR Journal Club 2007 October.

Relations between concurrent hard X-ray sources in solar flares M. Battaglia and A. O. Benz Presented by Jeongwoo Lee NJIT/CSTR Journal Club 2007 October.
Electron Acceleration at the Solar Flare Reconnection Outflow Shocks Gottfried Mann, Henry Aurass, and Alexander Warmuth Astrophysikalisches Institut Potsdam,

Electron Acceleration at the Solar Flare Reconnection Outflow Shocks Gottfried Mann, Henry Aurass, and Alexander Warmuth Astrophysikalisches Institut Potsdam,
RHESSI 2003 October 28 Time Histories Falling fluxes following the peak Nuclear/511 keV line flux delayed relative to bremsstrahlung Fit to 511 keV line.

RHESSI 2003 October 28 Time Histories Falling fluxes following the peak Nuclear/511 keV line flux delayed relative to bremsstrahlung Fit to 511 keV line.
Hard X-rays associated with CMEs H.S. Hudson, UCB & SPRC Y10, Jan. 24, 2001.

Hard X-rays associated with CMEs H.S. Hudson, UCB & SPRC Y10, Jan. 24, 2001.
24 Oct 2001 A Cool, Dense Flare T. S. Bastian 1, G. Fleishman 1,2, D. E. Gary 3 1 National Radio Astronomy Observatory 2 Ioffe Institute for Physics and.

24 Oct 2001 A Cool, Dense Flare T. S. Bastian 1, G. Fleishman 1,2, D. E. Gary 3 1 National Radio Astronomy Observatory 2 Ioffe Institute for Physics and.
X-Ray Observation and Analysis of a M1.7 Class Flare Courtney Peck Advisors: Jiong Qiu and Wenjuan Liu.

X-Ray Observation and Analysis of a M1.7 Class Flare Courtney Peck Advisors: Jiong Qiu and Wenjuan Liu.

Similar presentations

Ads by Google