Bibcode
Korzennik, Sylvain G.; Eff-Darwich, A.
Bibliographical reference
American Astronomical Society, AAS Meeting #218, #224.22; Bulletin of the American Astronomical Society, Vol. 43, 2011
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5
2011
Citations
0
Refereed citations
0
Description
We present the most exhaustive and accurate inferences of the internal
solar rotation rate and its evolution during solar cycle 23. A full
solar cycle of MDI observations have been analyzed using our state of
the art fitting methodology. Time series of various lengths have been
fitted, from a single 4608-day long epoch (64 times 72 day or 12.6 yr)
down to 64 separate segments for the "traditional" 72-day long epochs.
We used time series of spherical harmonic coefficients computed by the
MDI group but using an improved spatial decomposition. This
decomposition now includes our best estimate of the image plate scale
and of the MDI instrumental image distortion. The leakage matrix used
for the fitting includes the distortion of the eigenfunctions by the
solar differential rotation, and the undistorted leakage matrix was
itself carefully reviewed and independently recomputed. Rotation
inversions were carried out for all the available mode sets, fitted for
that epoch and all available segments, including the MDI and GONG
"pipe-line" sets. The improved inversions we used is an iterative
methodology based on a least-squares regularization. It also implement a
model grid optimization derived from the actual information in the input
set. This optimized model grid is itself irregular, namely with a
variable number of latitudes at different depths. We not only present
the most accurate mean rotation rate, but also how its derivation may
still be affected by uncertainties in the mode fitting (in particular
the leakage matrix). We also focus on the change of the rotation rate
with activity levels and how well these changes are significantly
assessed at higher latitudes as well as deeper in the solar interior,
down to the base of the convection zone.