Generation of Alfven Waves by Magnetic Reconnection

Slides:

Advertisements

Similar presentations

Particle acceleration in a turbulent electric field produced by 3D reconnection Marco Onofri University of Thessaloniki.

Advertisements

MHD Simulations of Flares and Jets in the Sun, Stars, and Accretion Disks Kazunari Shibata Kwasan and Hida Observatories Kyoto University East Asia Numerical.

1 Diagnostics of Solar Wind Processes Using the Total Perpendicular Pressure Lan Jian, C. T. Russell, and J. T. Gosling How does the magnetic structure.

Five Spacecraft Observations of Oppositely Directed Exhaust Jets from a Magnetic Reconnection X-line Extending > 4.3 x 10 6 km in the Solar Wind Gosling.

Nanoflares and MHD turbulence in Coronal Loop: a Hybrid Shell Model Giuseppina Nigro, F.Malara, V.Carbone, P.Veltri Dipartimento di Fisica Università della.

Construction of 3D Active Region Fields and Plasma Properties using Measurements (Magnetic Fields & Others) S. T. Wu, A. H. Wang & Yang Liu 1 Center for.

Do magnetic waves heat the solar atmosphere? Dr. E.J. Zita The Evergreen State College Fri.30.May 2003 at Reed College NW Section.

Selected Problems from Chapters 29 & 30. I 5I rd-r.

Winds of cool supergiant stars driven by Alfvén waves

SSL (UC Berkeley): Prospective Codes to Transfer to the CCMC Developers: W.P. Abbett, D.J. Bercik, G.H. Fisher, B.T. Welsch, and Y. Fan (HAO/NCAR)

Dissipation of Alfvén Waves in Coronal Structures Coronal Heating Problem T corona ~10 6 K M.F. De Franceschis, F. Malara, P. Veltri Dipartimento di Fisica.

Why does the temperature of the Sun’s atmosphere increase with height? Evidence strongly suggests that magnetic waves carry energy into the chromosphere.

Identifying Interplanetary Shock Parameters in Heliospheric MHD Simulation Results S. A. Ledvina 1, D. Odstrcil 2 and J. G. Luhmann 1 1.Space Sciences.

The Effect of Sub-surface Fields on the Dynamic Evolution of a Model Corona Goals :  To predict the onset of a CME based upon reliable measurements of.

Magnetic Reconnection Rate and Energy Release Rate Jeongwoo Lee 2008 April 1 NJIT/CSTR Seminar Day.

MHD Modeling of the Large Scale Solar Corona & Progress Toward Coupling with the Heliospheric Model.

Flux Tube Retraction Following Multiple Simultaneous Reconnection Events Daniel Gordon Supervisor: Dana Longcope Simulating Shocks in Solar Flares:

Coronal Heating of an Active Region Observed by XRT on May 5, 2010 A Look at Quasi-static vs Alfven Wave Heating of Coronal Loops Amanda Persichetti Aad.

Numerical simulations are used to explore the interaction between solar coronal mass ejections (CMEs) and the structured, ambient global solar wind flow.

Modelling of the Effects of Return Current in Flares Michal Varady 1,2 1 Astronomical Institute of the Academy of Sciences of the Czech Republic 2 J.E.

Magnetic Reconnection in Flares Yokoyama, T. (NAOJ) Reconnection mini-workshop Kwasan obs. Main Title 1.Introduction : Reconnection Model of.

Semi-Empirical MHD Modeling of the Solar Wind Igor V. Sokolov, Ofer Cohen, Tamas I. Gombosi CSEM, University of Michigan Ilia I Roussev, Institute for.

Boundaries, shocks, and discontinuities. How discontinuities form Often due to “wave steepening” Example in ordinary fluid: –V s 2 = dP/d  m –P/  

Three-dimensional MHD Simulations of Jets from Accretion Disks Hiromitsu Kigure & Kazunari Shibata ApJ in press (astro-ph/ ) Magnetohydrodynamic.

CSI /PHYS Solar Atmosphere Fall 2004 Lecture 09 Oct. 27, 2004 Ideal MHD, MHD Waves and Coronal Heating.

1 Searching for Alfvén Waves John Yoritomo The Catholic University of America Mentor: Dr. Adriaan van Ballegooijen The Smithsonian Astrophysical Observatory.

1 Numerical study of the thermal behavior of an Nb 3 Sn high field magnet in He II Slawomir PIETROWICZ, Bertrand BAUDOUY CEA Saclay Irfu, SACM Gif-sur-Yvette.

Space Science MO&DA Programs - September Page 1 SS It is known that the aurora is created by intense electron beams which impact the upper atmosphere.

Evolution of Emerging Flux and Associated Active Phenomena Takehiro Miyagoshi (GUAS, Japan) Takaaki Yokoyama (NRO, Japan)

Mass loss and Alfvén waves in cool supergiant stars Aline A. Vidotto & Vera Jatenco-Pereira Universidade de São Paulo Instituto de Astronomia, Geofísica.

3D simulations of solar emerging flux ISOBE Hiroaki Plasma seminar 2004/04/28.

Three-Dimensional MHD Simulation of Astrophysical Jet by CIP-MOCCT Method Hiromitsu Kigure (Kyoto U.), Kazunari Shibata (Kyoto U.), Seiichi Kato (Osaka.

Wave propagation in a non-uniform, magnetised plasma: Finite beta James McLaughlin Leiden March 2005.

II. MAGNETOHYDRODYNAMICS (Space Climate School, Lapland, March, 2009) Eric Priest (St Andrews)

Evolution of Flare Ribbons and Energy Release Rate Ayumi ASAI 1, Takaaki YOKOYAMA 2, Masumi SHIMOJO 3, Satoshi MASUDA 4, and Kazunari SHIBATA 1 1:Kwasan.

M. Onofri, F. Malara, P. Veltri Compressible magnetohydrodynamics simulations of the RFP with anisotropic thermal conductivity Dipartimento di Fisica,

Initial Conditions As an initial condition, we assume that an equilibrium disk rotates in a central point-mass gravitational potential (e.g., Matsumoto.

XRT and EIS Observations of Reconnection associated Phenomena D. Shiota, H. Isobe, D. H. Brooks, P. F. Chen, and K. Shibata

MHD wave propagation in the neighbourhood of a two-dimensional null point James McLaughlin Cambridge 9 August 2004.

A shock is a discontinuity separating two different regimes in a continuous media. –Shocks form when velocities exceed the signal speed in the medium.

Modeling 3-D Solar Wind Structure Lecture 13. Why is a Heliospheric Model Needed? Space weather forecasts require us to know the solar wind that is interacting.

Shock heating by Fast/Slow MHD waves along plasma loops

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Fall, 2009 Copyright © The Heliosphere: Solar Wind Oct. 08, 2009.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Sun: Magnetic Structure Feb. 16, 2012.

Global MHD Simulations of State Transitions and QPOs in Black Hole Accretion Flows Machida Mami (NAOJ) Matsumoto Ryoji (Chiba Univ.)

1 Fluid Theory: Magnetohydrodynamics (MHD). 2 3.

The heliospheric magnetic flux density through several solar cycles Géza Erdős (1) and André Balogh (2) (1) MTA Wigner FK RMI, Budapest, Hungary (2) Imperial.

Evolution of Flare Ribbons and Energy Release Ayumi ASAI 1, Takaaki YOKOYAMA 2, Masumi SHIMOJO 3, Satoshi MASUDA 4, Hiroki KUROKAWA 1, and Kazunari SHIBATA.

NIMROD Simulations of a DIII-D Plasma Disruption S. Kruger, D. Schnack (SAIC) April 27, 2004 Sherwood Fusion Theory Meeting, Missoula, MT.

GEM Student Tutorial: GGCM Modeling (MHD Backbone)

“Harris” Equilibrium: Initial State for a Broad Class of

Magnetic Reconnection in Solar Flares

Numerical Simulations of Solar Magneto-Convection

GOAL: To understand the physics of active region decay, and the Quiet Sun network APPROACH: Use physics-based numerical models to simulate the dynamic.

3-D Magnetohydrodynamics Simulation of the Solar Emerging Flux

Evolution of Flare Ribbons and Energy Release Ayumi Asai1,

Lecture 14 : Electromagnetic Waves

Evolution of Flare Ribbons and Energy Release Ayumi Asai (浅井歩)1,

Evolution of Flare Ribbons and Energy Release

Fluid Theory: Magnetohydrodynamics (MHD)

ESS 154/200C Lecture 19 Waves in Plasmas 2

The Bow Shock and Magnetosheath

Abstract We simulate the twisting of an initially potential coronal flux tube by photospheric vortex motions. The flux tube starts to evolve slowly(quasi-statically)

Introduction to Space Weather

Heavy-Ion Acceleration and Self-Generated Waves in Coronal Shocks

Coronal Loop Oscillations observed by TRACE

Evolution of Flare Ribbons and Energy Release

MHD Simulation of Plasmoid-Induced-Reconnection in Solar Flares

A Mach Number Behind a Slow Shock (Ahead a Fast

Periodic Acceleration of Electrons in Solar Flares

Presentation transcript:

Generation of Alfven Waves by Magnetic Reconnection Hiromitsu Kigure, Kazunari Shibata (Kyoto U.), Takaaki Yokoyama (Tokyo U.), Satoshi Nozawa (Ibaraki U.), Kunio Takahashi (NAOJ) kigure@kwasan.kyoto-u.ac.jp Abstract Results for 2.5-dimensional magnetohydrodynamical (MHD) simulations are reported for the magnetic reconnection of non-perfectly antiparallel magnetic fields. The magnetic field has a component perpendicular to the computational plane, that is, guide field. The angle between magnetic field lines in two half regions is a key parameter in our simulations. Alfven waves are generated at the reconnection point and propagate along the reconnected field line. The energy fluxes of the Alfven waves and slow-mode MHD waves generated by the magnetic reconnection are measured. Each flux shows the similar time evolution independent of . The percentage of the energies (time integral of energy fluxes) carried by the Alfven waves and slow-mode waves to the released magnetic energy are calculated. The Alfven waves carry 32.9%, 36.1%, and 34.4% of the released magnetic energy at the maximum in the case of =0.2, 1.0, and 10.0 respectively, where is the plasma (the ratio of gas pressure to magnetic pressure). The slow-mode waves carry 20.0%, 26.8%, and 62.9% of the energy at the maximum. Implications of these results for solar coronal heating and acceleration of high-speed solar wind are discussed. Time Evolution Left figures show the time evolution of the logarithmic pressure, and right figures (except the bottom figure) show the time evolution of the magnetic field component perpendicular to the initial field in the case of and . The bottom figure of the right panel shows the Bz distribution at t=30.0. MHD Equations, Numerical Method, Resistivity, Initial Condition, etc. These equations are numerically solved by the Lax-Wendroff module in CANS (Coordinated Astronomical Numerical Softwares), which is an integrated code to simulate astrophysical magnetohydrodynamic phenomena. These are schematic pictures of the initial magnetic field. To decide the initial magnetic field distribution, there are two parameters. One is the plasma beta, and another is the angle between the magnetic field lines in two half regions. The gas pressure distribution is designed to satisfy the total pressure equilibrium, and the density distribution is decided under the condition that initial sound velocity is unity in the all computational domain. The periodic boundary condition is adopted at the all boundaries. Energy Fluxes of Alfven Waves and Slow-mode Waves The energy fluxes carried by the Alfven waves and slow-mode waves generated by the magnetic reconnection are measured on a line where . The definitions are as follows: Percentage of the Energies Carried by Waves to the Released Magnetic Energy , where means the difference from the initial value. The plus sign is on the the y=10.0 line and the minus sign on the y=－10.0 line. We also measure the time integral of each flux: The origin of the energies transported by the Alfven waves and slow-mode waves is the magnetic energy released by the reconnection so that the magnetic energy in the simulation domain is also measured. These figures show the percentage of the energies carried by the Alfven waves and slow-mode waves to the released magnetic energy. The horizontal axis shows the parameter , and the vertical axis shows the percentage. As decreases the percentage of the energy carried by the Alfven waves increases up to 32.9%, 36.1%, and 34.4% in the case of =0.2, 1.0, and 10.0 respectively, and then decreases. The percentage is maximum when = 80° or 90°.　The percentage of the energy carried by the slow-mode　waves is almost constant when is relatively large in the cases of =0.2 and 1.0 while it gradually decreases in the case of =10.0. The maximum values are 20.0%, 26.8%, and 62.9% in the case of =0.2, 1.0, and 10.0 respectively. The total non-radiative energy input to the solar coronal hole was estimated at ergs cm-2 s-1 by Withbroe (1988). For the acceleration of high-speed solar wind, some ergs cm-2 s-1 is required to be deposited at distances of several solar radii (see, e.g., Parker 1991, and references therein). If the solar wind is accelerated by the energy flux of Alfven waves, this means that 20% of the energy released by reconnection events in the solar corona is transferred as a form of Alfven wave. Our results show that the energy larger than the required can be carried by the Alfven wave independent of around the parametric region of . These energies are converted to thermal energy through the dissipation of Alfven waves. Time evolution of the energy flux, F, of (a)Alfven waves and (b)slow-mode waves in each case. Time evolution of the time integral of energy flux carried by (c)Alfven waves and (d)slow-mode waves in each case. The plasma beta is 0.2.