Presentation is loading. Please wait.

Presentation is loading. Please wait.

Solar and Heliospheric Physics

Published byMilo Horton Modified over 5 years ago

Similar presentations

Presentation on theme: "Solar and Heliospheric Physics"— Presentation transcript:

1 Solar and Heliospheric Physics
Magnetic Field Sep. 9 – Sep. 30, 2010 CSI Fall Jie Zhang

2 Magnetic Fields References: Aschwanden: Chap. 5.1 – 5.6
Supplement articles for PFSS model Altschuler, Martin D., Newkirk, Gordon, Jr., Magnetic Fields and the Structure of the Solar Corona, Solar Physics 9, , 1969 Sakurai, Takashi., Green’s Function Methods for Potential Magnetic Fields, Solar Physics 76, , 1982 Schrijver, Carolus J., Derosa, Marc K., Photospheric and Heliospheric Magnetic Fields, Solar Physics, 212: , 2003 For NLFF model Schrijver et al. 2006, Solar Physics 235, P “Non-Linear Force Free Modeling of Coronal magnetic Fields Part 1: A Quantitative Comparison of Methods

3 Why? Why is the corona highly structured? Why is it hot?
Why is it explosive? Why highly structured? Holes, loop arcades, s-shaped loops, flux rope stricutre Why is hot? That leads to expansion into solar wind Why is explosive, leading to flares and CMEs, the sources of space weather Corona in X-ray

4 Photospheric Magnetic Field Magnetogram Continuum Image
Magnetogram: measurement of magnetic in the photosphere Nature of sunspot: areas of concentration of strong magnetic field Magnetogram Continuum Image

5 Hale’s Polarity Law + - + - + + - + - -

6 Hale’s Polarity Law Sunspots are grouped in pairs of opposite polarities The ordering of leading polarity/trailing polarity with respect to the east-west direction (direction of rotation) is the same in a given hemisphere, but is reversed from northern to southern hemisphere The leading polarity of sunspots is the same as the polarity in the polar region of the same hemisphere From one sunspot cycle to the next, the magnetic polarities of sunspot pairs undergo a reversal in each hemisphere. The Hale cycle is 22 years, while the sunspot cycle is 11 years

7 Solar Magnetic Cycle Butterfly diagram of Magnetic Field
Global dipole field most of the time Polar field reversal during the solar maximum

8 Other Laws Sporer’s Law: Sunspot emerge at relatively high latitudes and move towards the equator Joy’s Law: The tilt angle of the active regions is proportional to the latitude

9 Solar Cycle 11-year cycle of sunspot number (SSN)
SSN is historically a good index of solar activity. Correlate well with geomagnetic activities

10 Butterfly Diagram of Sunspot
A diagram shows the position (latitude) of sunspot with time It describe the movement of sunspot in the time scale of solar cycle

11 Butterfly Diagram of Sunspot
Sunspots do not appear at random over the surface of the sun. At any time, they are concentrated in two latitude bands on either side of the equator. But these bands move with time At the start of a cycle, these bands form at mid-latitudes (~30°) As cycle progresses, they move toward the equator. As cycle progresses, sunspot bands becomes wider At the end of cycle, sunspots are close to equator and then disappear At the minimum of the cycle, old cycle spots near the equator overlaps in time with new cycle spots at high latitudes

12 Coronal Magnetic Field
Schrijver & Derosa, 2003 Magnetogam image, coronal loops, extrapolated coronal magnetic field

13 Coronal Magnetic Field
Feb. 2, 2008 Synoptic calculation Surface magnetogram used data assimilation to take into account the evolution on the backside of the Sun.

14 Potential Field Aschwanden 5.2 Unipolar field Dipole field
Potential field calculation methods Green’s function methods Eigenfunction expansion methods PFSS model

15 Result of the Analytical Model
Single Sunspot Field Aschwanden 5.2.1, P Result of the Analytical Model

16 Result of the Analytical Model
Dipole Field Aschwanden 5.2.2, P Result of the Analytical Model

17 Force-Free Field Force free field: Asch-Chap. 5.3.1
Non-Linear force free field: Asch-Chap Shear arcade: Asch-Chap An example of linear force free field Magnetic Nullpoints and Separators: Asch – Chap. 5.6

18 Loop Arcade Loop arcade seen by TRACE (Credit: NASA)

19 Loop Arcade Loop arcade seen by TRACE (Credit: NASA)

20 Loop Arcade Loop arcade, shear motion, and formation of prominence (Van Ballegooijen & Martens, 1989)

21 Loop Arcade Force Free Field of a Sheared Arcade – Analytic Solution (Asch—Fig. 5.4)

22 Nullpoint & Separatrix
(Asch—Fig. 5.22)

23 Nullpoints 2-D X-point (left) and O-point (Asch—Fig. 5.24)
Ref: Asch--Chap Priest—Chap. 1.3

24 The End

Download ppt "Solar and Heliospheric Physics"

Similar presentations

Sunspots and the Scientific Method: Models. Hypothesis Driven Science Hypothesis: An educated speculation about how a particular phenomenon behaves- very.

Sunspots and the Scientific Method: Models. Hypothesis Driven Science Hypothesis: An educated speculation about how a particular phenomenon behaves- very.
Estimating the magnetic energy in solar magnetic configurations Stéphane Régnier Reconnection seminar on Thursday 15 December 2005.

Estimating the magnetic energy in solar magnetic configurations Stéphane Régnier Reconnection seminar on Thursday 15 December 2005.
An overview of the cycle variations in the solar corona Louise Harra UCL Department of Space and Climate Physics Mullard Space Science.

An overview of the cycle variations in the solar corona Louise Harra UCL Department of Space and Climate Physics Mullard Space Science.
Chapter 8 The Sun – Our Star.

Chapter 8 The Sun – Our Star.
The Hemispheric Pattern of Filaments and Consequences for Filament Formation Duncan H Mackay Solar Physics Group University of St. Andrews.

The Hemispheric Pattern of Filaments and Consequences for Filament Formation Duncan H Mackay Solar Physics Group University of St. Andrews.
Show 1 -- photosphere & sunspots--> SUN COURSE - SLIDE SHOW 2 1. Introduction, 2. Magnetic fields, 3. Corona.

Show 1 -- photosphere & sunspots--> SUN COURSE - SLIDE SHOW 2 1. Introduction, 2. Magnetic fields, 3. Corona.
The Relation between Filament Skew Angle and Magnetic Helicity of Active Regions Masaoki HAGINO, Y.J. MOON (Korea Astronomy and Space Science Institute)

The Relation between Filament Skew Angle and Magnetic Helicity of Active Regions Masaoki HAGINO, Y.J. MOON (Korea Astronomy and Space Science Institute)
Comparing the Large-Scale Magnetic Field During the Last Three Solar Cycles Todd Hoeksema.

Comparing the Large-Scale Magnetic Field During the Last Three Solar Cycles Todd Hoeksema.
Evolution of the Large-Scale Magnetic Field Over Three Solar Cycles Todd Hoeksema.

Evolution of the Large-Scale Magnetic Field Over Three Solar Cycles Todd Hoeksema.
High-latitude activity and its relationship to the mid-latitude solar activity. Elena E. Benevolenskaya & J. Todd Hoeksema Stanford University Abstract.

High-latitude activity and its relationship to the mid-latitude solar activity. Elena E. Benevolenskaya & J. Todd Hoeksema Stanford University Abstract.
Tucson MURI SEP Workshop 17-18 March 2003 Janet Luhmann and the Solar CISM Modeling Team Solar and Interplanetary Modeling.

Tucson MURI SEP Workshop March 2003 Janet Luhmann and the Solar CISM Modeling Team Solar and Interplanetary Modeling.
1 Synoptic Maps of Magnetic Field from MDI Magnetograms: polar field interpolation. Y. Liu, J. T. Hoeksema, X. P. Zhao, R. M. Larson – Stanford University.

1 Synoptic Maps of Magnetic Field from MDI Magnetograms: polar field interpolation. Y. Liu, J. T. Hoeksema, X. P. Zhao, R. M. Larson – Stanford University.
The May 1,1998 and May 12, 1997 MURI events George H. Fisher UC Berkeley.

The May 1,1998 and May 12, 1997 MURI events George H. Fisher UC Berkeley.
1 A Statistical Study about Transequatorial loops Jie Chen National Astronomical Observatories Chinese Academy of Sciences.

1 A Statistical Study about Transequatorial loops Jie Chen National Astronomical Observatories Chinese Academy of Sciences.
Space Weather Forecast With HMI Magnetograms: Proposed data products Yang Liu, J. T. Hoeksema, and HMI Team.

Space Weather Forecast With HMI Magnetograms: Proposed data products Yang Liu, J. T. Hoeksema, and HMI Team.
The nature of impulsive solar energetic particle events N. V. Nitta a, H. S. Hudson b, M. L. Derosa a a Lockheed Martin Solar and Astrophysics Laboratory.

The nature of impulsive solar energetic particle events N. V. Nitta a, H. S. Hudson b, M. L. Derosa a a Lockheed Martin Solar and Astrophysics Laboratory.
Sung-Hong Park Space Weather Research Laboratory New Jersey Institute of Technology Study of Magnetic Helicity and Its Relationship with Solar Activities:

Sung-Hong Park Space Weather Research Laboratory New Jersey Institute of Technology Study of Magnetic Helicity and Its Relationship with Solar Activities:
The May 1997 and May 1998 MURI events George H. Fisher UC Berkeley.

The May 1997 and May 1998 MURI events George H. Fisher UC Berkeley.
Thomas Zurbuchen University of Michigan The Structure and Sources of the Solar Wind during the Solar Cycle.

Thomas Zurbuchen University of Michigan The Structure and Sources of the Solar Wind during the Solar Cycle.
A topological view of 3D global magnetic field reversal in the solar corona Rhona Maclean Armagh Observatory 5 th December 2006.

A topological view of 3D global magnetic field reversal in the solar corona Rhona Maclean Armagh Observatory 5 th December 2006.

Similar presentations

Ads by Google