Imaging Solar Tachocline Using Numerical Simulations and

SOHO/MDI DataJunwei Zhao1, Thomas Hartlep2, Alexander G.

Kosovichev1, Nagi N. Mansour2

1. W.W.Hansen Experimental Physics Laboratory, Stanford University, Stanford, CA94305-4085

2. NASA Ames Research Center, Moffett Field, CA94035

Tachocline Imaging Using Numerical Simulation Data

Simulation Model

Sound-speed perturbation of 0.6% is placed at 0.7R, with a latitudinal dependence, and with a Gaussian shape. It’s symmetric along the equator.

The simulation used here is 1024 minutes.

Measurement Scheme: Surface Focusing•We use surface-focusing scheme, also averaging around annulus. Annulus radii range from 6 to 86 degrees, and annulus width is 1 pixel size, i.e., 0.6 degree; Postel’s projection is used.•No any filtering is used except that filtering out f-modes and convection;•The central pixel location ranges from -60 to 60 degrees in both latitude and longitude;•After all measurements, collapse all pixels of the same latitude into one;•In the end, we have 200 numbers in latitude and 131 numbers in annulus radii.

R

0.45R

Measured Travel Times

Measured travel times are displayed after a reference profile is subtracted. The reference profile is measured from a simulation that Thomas Hartlep made without perturbations.

Inversion

• Inversion kernels were made based on ray-approximation;

• Inversion was performed by use of Multi-Channel Deconvolution, which was a code easier to write than other least square inversion techniques.

• Regularization was only used in vertical direction.• In the radial direction, the resolution we used was

5Mm/pixel.

Inversion Result

Comparing Inversion Result with Model

• The inversion result seems not well localized, the perturbation is widely spread into all other areas. • Seems a feature at 0.6R equator was something brought down by the ray path.

Comparing Inversion Result with Model

1D result that was averaged from all latitudes once again show that inversion was not well localized.

Averaging kernels should be computed to see how localized our inversions are.

Measurement Scheme: Deep Focusing•I also use deep-focusing scheme, averaging around annulus as well. Annulus radii also range from 6 to 86 degrees, and annulus width is 1 pixel size, i.e., 0.6 degr;•No any filtering is used except that filtering out f-modes and convection;•The central pixel location ranges from -60 to 60 in both latitude and longitude;•After all measurements, collapse all pixels of the same latitude into one;•In the end, I have 200 numbers in latitude and 66 numbers in annulus radii.

R

0.45R

Measured Travel Times

Travel times are displayed after the reference is subtracted. The reference is from measuring quiet Sun simulation as well. Some Gaussian smoothing was done to reduce noises.

Deep Focusing Inversion Result

Results are not so good as surface focusing results.

One reason is that measurement noises are quite high.

Deep Focusing Inversion Result

Once again, the inverted profile seems not well localized.

Tachocline Imaging Using Observational Data

Applying the Analysis on Observations

• 1440-minute (1 day) medium-l datasets are used;• To infer one tachocline image, I used one Carrington

rotation’s simulation to average, i.e., 27 datasets.• EXACTLY the same measurement and inversion

procedure was applied to the real observation as used in simulated data

• Note that the reference profile is also the same as that is used in simulated data, i.e., travel times measured from quiet Sun simulation.

Measurements from Real Sun: Surface Focusing

Results from Real Sun: Surface Focusing

• Structures are not hemisphere symmetric.• Tachocline is clearly seen, pretty much latitudinal dependent.

Measurements from Real Sun: Deep Focusing

Results from Real Sun: Deep Focusing

• Again, structures are not hemisphere symmetric.• Tachocline is also clearly seen, latitudinal dependent.

Results: Comparing with Global Helioseismology Result

• Red and pink curves are from surface- and deep-focus, respectively.• Tachocline is surprisingly in good agreement! • Should keep in mind the experiments using simulated data show that results are not well localized.

Tachocline Variations with Solar Cycle

I kept some Stanford computers running continuously for about 3 months, and obtained 11 years’ far-side images, 11 years’ interior sound speed images, 11 years’ interior rotations, and 11 years’ meridional flow priofiles, all from time-distance technique, and all from MDI medium-l data.

Tachocline Variations from August 1996 to August 2007

Results Are Not Exciting, But Rather, Disappointing

Seems that results are very much instrument sensitive. When SOHO rotates upside-down due to the key-hole issue, inverted results are also upside-down.

Even if we neglect the instrument effect, the travel time variations are caused by interior sound-speed perturbation together with the interior magnetic field. I should not invert without the magnetic field term.

All previous analyses were wrong.

Even if I had inverted with both terms, how about surface effects?

Correlation with Magnetic Field

I am facing the same problem as Rachel in her frequency shift analysis. Is the interior sound speed perturbation caused by interior magnetic field, or is it just caused by surface effect?

Summary• Local Helioseismology is useful to get global results;

• It is interesting that we can get the sound-speed bump at the location of tachocline by use of both surface and deep-focusing;

• It is quite annoying that seems MDI instrument can bring lots of troubles in the analysis;

• It is not known, but certainly worth further studying to understand the correlation of sound-speed perturbation with the magnetic field.

• Can we infer the interior magnetic field from such an analysis?