Presentation is loading. Please wait.

Presentation is loading. Please wait.

Numerical simulation of effects of reduced excitationof 5-min.solar oscillations in sunspots Konstantin Parchevsky, Alexander Kosovichev Stanford University,

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Numerical simulation of effects of reduced excitationof 5-min.solar oscillations in sunspots Konstantin Parchevsky, Alexander Kosovichev Stanford University,"— Presentation transcript:

1 Numerical simulation of effects of reduced excitationof 5-min.solar oscillations in sunspots Konstantin Parchevsky, Alexander Kosovichev Stanford University, HEPL

2 Motivation The amplitude of 5-min. oscillations is significantly smaller in sunspots than in the quiet Sun. The amplitude of 5-min. oscillations is significantly smaller in sunspots than in the quiet Sun. Lack of wave sources inside sunspots where convection is suppressed by strong magnetic field. Lack of wave sources inside sunspots where convection is suppressed by strong magnetic field. Interaction of incoming waves with magnetic field and perturbations of pressure and density inside sunspots. Interaction of incoming waves with magnetic field and perturbations of pressure and density inside sunspots.

3

4 k-  diagram simulations observations

5 Artificial mask

6 Amplitude maps observations simulations  = 3.65 ± 0.6 mHz amplitude ratio:4.0 ± 0.94.6 ± 1.0 MDI continuum 120  120  50 Mm 3

7 Amplitude ratio vs. sunspot diameter

8 Conclusion 1. The suppression of acoustic sources inside sunspots can almost entirely explain the reduced oscillation amplitude observed in sunspots. 2. Amplitude ratio of acoustic waves inside and outside sunspots depends on sunspots radii. The bigger radius, the bigger suppression.

Download ppt "Numerical simulation of effects of reduced excitationof 5-min.solar oscillations in sunspots Konstantin Parchevsky, Alexander Kosovichev Stanford University,"

Similar presentations

Numerical Simulations of Supergranulation and Solar Oscillations Åke Nordlund Niels Bohr Institute, Univ. of Copenhagen with Bob Stein (MSU) David Benson,

Numerical Simulations of Supergranulation and Solar Oscillations Åke Nordlund Niels Bohr Institute, Univ. of Copenhagen with Bob Stein (MSU) David Benson,
Tsing Hua University, Taiwan Solar Acoustic Holograms January 2008, Tucson Dean-Yi Chou.

Tsing Hua University, Taiwan Solar Acoustic Holograms January 2008, Tucson Dean-Yi Chou.
Lunar Results Hybrid code. Initial condition Amplitude of dipole for the moon= 0 Lunar Radius=16.9 (unit of length) Maximum time = 200(inverse of gyro.

Lunar Results Hybrid code. Initial condition Amplitude of dipole for the moon= 0 Lunar Radius=16.9 (unit of length) Maximum time = 200(inverse of gyro.
Initial Analysis of the Large-Scale Stein-Nordlund Simulations Dali Georgobiani Formerly at: Center for Turbulence Research Stanford University/ NASA Presenting.

Initial Analysis of the Large-Scale Stein-Nordlund Simulations Dali Georgobiani Formerly at: Center for Turbulence Research Stanford University/ NASA Presenting.
Solar Convection: What it is & How to Calculate it. Bob Stein.

Solar Convection: What it is & How to Calculate it. Bob Stein.
Phase Coherence on Open Field Lines Associated with FLRs Abiyu Nedie, Frances Fenrich & Robert Rankin University of Alberta Edmonton, Alberta, Canada 2011.

Phase Coherence on Open Field Lines Associated with FLRs Abiyu Nedie, Frances Fenrich & Robert Rankin University of Alberta Edmonton, Alberta, Canada 2011.
Holography & HMI NorthWest Research Associates, Inc. Colorado Research Associates Division D. Braun, C. Lindsey, A. Birch (NWRA/CoRA) collaborators: P.

Holography & HMI NorthWest Research Associates, Inc. Colorado Research Associates Division D. Braun, C. Lindsey, A. Birch (NWRA/CoRA) collaborators: P.
TIME-DISTANCE ANALYSIS OF REALISTIC SIMULATIONS OF SOLAR CONVECTION Dali Georgobiani, Junwei Zhao 1, David Benson 2, Robert Stein 2, Alexander Kosovichev.

TIME-DISTANCE ANALYSIS OF REALISTIC SIMULATIONS OF SOLAR CONVECTION Dali Georgobiani, Junwei Zhao 1, David Benson 2, Robert Stein 2, Alexander Kosovichev.
Summary. Two directions in modeling Adopting physical (realistic) models Creating artificial data sets with simplified physics.

Summary. Two directions in modeling Adopting physical (realistic) models Creating artificial data sets with simplified physics.
Solar Physics & upper Atmosphere Research Group University of Sheffield A possible method for measuring the plasma density profile along coronal loops.

Solar Physics & upper Atmosphere Research Group University of Sheffield A possible method for measuring the plasma density profile along coronal loops.
On the Cause of Solar Differential Rotation Ling-Hsiao Lyu Institute of Space Science, National Central University 呂凌霄 中央大學太空科學研究所 太陽差動自轉的成因.

On the Cause of Solar Differential Rotation Ling-Hsiao Lyu Institute of Space Science, National Central University 呂凌霄 中央大學太空科學研究所 太陽差動自轉的成因.
Transformation of MHD waves in sunspots and simulation of HMI level1 data Konstantin Parchevsky, Sebastien Couvidat, Richard Wachter, Alexander Kosovichev.

Transformation of MHD waves in sunspots and simulation of HMI level1 data Konstantin Parchevsky, Sebastien Couvidat, Richard Wachter, Alexander Kosovichev.
Why does the temperature of the Sun’s atmosphere increase with height? Evidence strongly suggests that magnetic waves carry energy into the chromosphere.

Why does the temperature of the Sun’s atmosphere increase with height? Evidence strongly suggests that magnetic waves carry energy into the chromosphere.
Near-surface simulations of the acoustic field Konstantin Parchevsky Stanford University, HEPL.

Near-surface simulations of the acoustic field Konstantin Parchevsky Stanford University, HEPL.
Astronomy 100 Tuesday, Thursday 2:30 - 3:45 pm Tom Burbine

Astronomy 100 Tuesday, Thursday 2:30 - 3:45 pm Tom Burbine
Detection of Emerging Sunspot Regions in the Solar Interior Stathis Ilonidis, Junwei Zhao, and Alexander Kosovichev Stanford University LoHCo Workshop.

Detection of Emerging Sunspot Regions in the Solar Interior Stathis Ilonidis, Junwei Zhao, and Alexander Kosovichev Stanford University LoHCo Workshop.
MDI Level 1.8 Magnetograms Yang Liu Stanford University 6/23/2008 1 SHINE 2008.

MDI Level 1.8 Magnetograms Yang Liu Stanford University 6/23/ SHINE 2008.
Five minute solar oscillation power within magnetic elements Rekha Jain & Andrew Gascoyne School of Mathematics and Statistics (SoMaS) University of Sheffield.

Five minute solar oscillation power within magnetic elements Rekha Jain & Andrew Gascoyne School of Mathematics and Statistics (SoMaS) University of Sheffield.
What Dynamic Changes in the Sun Drive the Evolution of Oscillation Frequencies through the Activity Cycle? Philip R. Goode Big Bear Solar Observatory New.

What Dynamic Changes in the Sun Drive the Evolution of Oscillation Frequencies through the Activity Cycle? Philip R. Goode Big Bear Solar Observatory New.
An Introduction to Helioseismology (Local) 2008 Solar Physics Summer School June 16-20, Sacramento Peak Observatory, Sunspot, NM.

An Introduction to Helioseismology (Local) 2008 Solar Physics Summer School June 16-20, Sacramento Peak Observatory, Sunspot, NM.

Similar presentations

Ads by Google