Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ward Manchester University of Michigan Coupling of the Coronal and Subphotospheric Magnetic Field in Active Regions by Shear Flows Driven by The Lorentz.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Ward Manchester University of Michigan Coupling of the Coronal and Subphotospheric Magnetic Field in Active Regions by Shear Flows Driven by The Lorentz."— Presentation transcript:

1 Ward Manchester University of Michigan Coupling of the Coronal and Subphotospheric Magnetic Field in Active Regions by Shear Flows Driven by The Lorentz Force Coupling of the Coronal and Subphotospheric Magnetic Field in Active Regions by Shear Flows Driven by The Lorentz Force

2 Outline Universal feature of active regions that produce CMEs: magnetic shear Universal feature of active regions that produce CMEs: magnetic shear Source of magnetic shear: a subtle combination of the Lorentz force and gravitational pressure stratification of the solar atmosphere Source of magnetic shear: a subtle combination of the Lorentz force and gravitational pressure stratification of the solar atmosphere Examples of shearing motions in flux ropes, and magnetic layers Examples of shearing motions in flux ropes, and magnetic layers Picture of magnetic activity that couples the subphotospheric magnetic field to the corona Picture of magnetic activity that couples the subphotospheric magnetic field to the corona

3 Velocity and Magnetic Shear in AR 10486 Source of the Halloween Events Velocity Shear Yang et al. 2004, ApJ 617 L151, Magnetic Shear Liu et al. 2005, ApJ 622, 722 Velocity Shear Yang et al. 2004, ApJ 617 L151, Magnetic Shear Liu et al. 2005, ApJ 622, 722

4 Recent CME Models That Impose Shear Magnetic Arcade Models Imposed shearing of foot points with magnetic reconnect at the base of the arcade (Amari et al. 2003 ApJ 595, 1231 ) Imposed shearing of foot points with magnetic reconnect at the base of the arcade (Amari et al. 2003 ApJ 595, 1231 ) Break-out model: Imposed shearing motions and reconnection above the arcade in a quadruple system (Antiochos 1999 ApJ 510, 485) Break-out model: Imposed shearing motions and reconnection above the arcade in a quadruple system (Antiochos 1999 ApJ 510, 485)

5 Emergence of a 3D flux rope Manchester, Gombosi, De Zeeuw and Fan. 2004, ApJ 610, 588

6 Flux Rope Emerging From the Convection Zone into the Corona Buoyant section of the flux rope reduced by a factor of two Buoyant section of the flux rope reduced by a factor of two

7 Spontaneous Shearing Motions Opposite sides of the flux rope move in opposite directions as the flux rope expands. Opposite sides of the flux rope move in opposite directions as the flux rope expands. Motions are driven by the Lorentz force! Motions are driven by the Lorentz force!

8 Development and Eruption of Magnetic Shear Core

9 The Lorentz Force Drives the Shearing!! Shearing motions transport Bx flux into the expanding portion of the flux rope and tends to return Bx to constant values along field lines to restore force balance

10

11 Dynamic Coupling By Shear Flows

12 Shearing During Flux Emergence From a Magnetic Layer

13 Comparison of Shear Velocity The image on the left, the shear velocity at the mid-plane of the simulation is shown. On the right, Doppler velocity maps of active regions at the limb made with SUMER Chae et al. 2000, ApJ 533, 535,

14 Conclusions Shearing motions are a consequence of the Lorentz force that arises as the magnetic field expands in a highly stratified atmosphere which naturally explains: Shearing motions are a consequence of the Lorentz force that arises as the magnetic field expands in a highly stratified atmosphere which naturally explains: Magnitude of the shear velocity in the photosphere, chromosphere and corona that occur at a characteristic fraction of the local Alfven speed. Magnitude of the shear velocity in the photosphere, chromosphere and corona that occur at a characteristic fraction of the local Alfven speed. Shearing motions transport axial flux into expanding portion of flux rope or arcade and acts to return the axial component to constant values along field lines Shearing motions transport axial flux into expanding portion of flux rope or arcade and acts to return the axial component to constant values along field lines These shear flows strongly couple the low  corona to the high  photosphere and convection zone These shear flows strongly couple the low  corona to the high  photosphere and convection zone

15 Fundamental Assumptions The Sun possesses a gravitational field that results in large pressure stratification of the atmosphere The Sun possesses a gravitational field that results in large pressure stratification of the atmosphere Non-force-free magnetic structures pass that through the photosphere into the corona to form active regions are MUCH larger than pressure scale height at the photosphere (140 km) Non-force-free magnetic structures pass that through the photosphere into the corona to form active regions are MUCH larger than pressure scale height at the photosphere (140 km) Magnetic fields possess a horizontal axial component in addition to an azimuthal component Magnetic fields possess a horizontal axial component in addition to an azimuthal component The Lorentz force represented as (curl B) X B reverses direction across the expanding structure The Lorentz force represented as (curl B) X B reverses direction across the expanding structure Very general as it applies to flux ropes, arcades and magnetic layers Very general as it applies to flux ropes, arcades and magnetic layers

16 Thank You

Download ppt "Ward Manchester University of Michigan Coupling of the Coronal and Subphotospheric Magnetic Field in Active Regions by Shear Flows Driven by The Lorentz."

Similar presentations

Lecture 9 Prominences and Filaments Filaments are formed in magnetic loops that hold relatively cool, dense gas suspended above the surface of the Sun,

Lecture 9 Prominences and Filaments Filaments are formed in magnetic loops that hold relatively cool, dense gas suspended above the surface of the Sun,"
Observations on Current Sheet and Magnetic Reconnection in Solar Flares Haimin Wang and Jiong Qiu BBSO/NJIT.

Observations on Current Sheet and Magnetic Reconnection in Solar Flares Haimin Wang and Jiong Qiu BBSO/NJIT.
The magnetic nature of solar flares Paper by E.R. Priest & T.G. Forbes Review presented by Hui Song.

The magnetic nature of solar flares Paper by E.R. Priest & T.G. Forbes Review presented by Hui Song.
The Relationship Between CMEs and Post-eruption Arcades Peter T. Gallagher, Chia-Hsien Lin, Claire Raftery, Ryan O. Milligan.

The Relationship Between CMEs and Post-eruption Arcades Peter T. Gallagher, Chia-Hsien Lin, Claire Raftery, Ryan O. Milligan.
TRACE and RHESSI observations of the failed eruption of the magnetic flux rope Tomasz Mrozek Astronomical Institute University of Wrocław.

TRACE and RHESSI observations of the failed eruption of the magnetic flux rope Tomasz Mrozek Astronomical Institute University of Wrocław.
CME/Flare Mechanisms Solar “minimum” event this January For use to VSE must be able to predict CME/flare Spiro K. Antiochos Naval Research Laboratory.

CME/Flare Mechanisms Solar “minimum” event this January For use to VSE must be able to predict CME/flare Spiro K. Antiochos Naval Research Laboratory.
Magnetic Reconnection Across the HCS Mark Moldwin UM and Megan Cartwright UC-Berkeley Isradynamics April 2010 With thanks to Mark Linton at NRL Linton.

Magnetic Reconnection Across the HCS Mark Moldwin UM and Megan Cartwright UC-Berkeley Isradynamics April 2010 With thanks to Mark Linton at NRL Linton.
General Properties Absolute visual magnitude M V = 4.83 Central temperature = 15 million 0 K X = 0.73, Y = 0.25, Z = 0.02 Initial abundances: Age: ~ 4.52.

General Properties Absolute visual magnitude M V = 4.83 Central temperature = 15 million 0 K X = 0.73, Y = 0.25, Z = 0.02 Initial abundances: Age: ~ 4.52.
Nanoflares and MHD turbulence in Coronal Loop: a Hybrid Shell Model Giuseppina Nigro, F.Malara, V.Carbone, P.Veltri Dipartimento di Fisica Università della.

Nanoflares and MHD turbulence in Coronal Loop: a Hybrid Shell Model Giuseppina Nigro, F.Malara, V.Carbone, P.Veltri Dipartimento di Fisica Università della.
STEREO AND SPACE WEATHER Variable conditions in space that can have adverse effects on human life and society Space Weather: Variable conditions in space.

STEREO AND SPACE WEATHER Variable conditions in space that can have adverse effects on human life and society Space Weather: Variable conditions in space.
Chip Manchester, Fang Fang, Bill Abbett, Bart van der Holst Patterns of Large- Scale Flux Emegence Patterns of Large- Scale Flux Emegence.

Chip Manchester, Fang Fang, Bill Abbett, Bart van der Holst Patterns of Large- Scale Flux Emegence Patterns of Large- Scale Flux Emegence.
Modeling the Magnetic Field Evolution of the December 13 2006 Eruptive Flare Yuhong Fan High Altitude Observatory, National Center for Atmospheric Research.

Modeling the Magnetic Field Evolution of the December Eruptive Flare Yuhong Fan High Altitude Observatory, National Center for Atmospheric Research.
Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,

Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,
Chip Manchester 1, Fang Fang 1, Bart van der Holst 1, Bill Abbett 2 (1)University of Michigan (2)University of California Berkeley Study of Flux Emergence:

Chip Manchester 1, Fang Fang 1, Bart van der Holst 1, Bill Abbett 2 (1)University of Michigan (2)University of California Berkeley Study of Flux Emergence:
Two energy release processes for CMEs: MHD catastrophe and magnetic reconnection Yao CHEN Department of Space Science and Applied Physics Shandong University.

Two energy release processes for CMEs: MHD catastrophe and magnetic reconnection Yao CHEN Department of Space Science and Applied Physics Shandong University.
Simulations of Emerging Magnetic Flux in Active Regions W. P. Abbett Space Sciences Laboratory University of California, Berkeley.

Simulations of Emerging Magnetic Flux in Active Regions W. P. Abbett Space Sciences Laboratory University of California, Berkeley.
SHINE 20051 The Role of Sub-Surface Processes in the Formation of Coronal Magnetic Flux Ropes A. A. van Ballegooijen Smithsonian Astrophysical Observatory.

SHINE The Role of Sub-Surface Processes in the Formation of Coronal Magnetic Flux Ropes A. A. van Ballegooijen Smithsonian Astrophysical Observatory.
Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.

Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.
Prediction of Central Axis Direction of Magnetic Clouds Xuepu Zhao and Yang Liu Stanford University The West Pacific Geophysics Meeting, Beijing, China.

Prediction of Central Axis Direction of Magnetic Clouds Xuepu Zhao and Yang Liu Stanford University The West Pacific Geophysics Meeting, Beijing, China.
Center for Space Environment Modeling Ward Manchester University of Michigan Yuhong Fan High Altitude Observatory SHINE July.

Center for Space Environment Modeling Ward Manchester University of Michigan Yuhong Fan High Altitude Observatory SHINE July.

Similar presentations

Ads by Google