Bibcode
DOI
Schou, J.; Antia, H. M.; Basu, S.; Bogart, R. S.; Bush, R. I.; Chitre, S. M.; Christensen-Dalsgaard, J.; di Mauro, M. P.; Dziembowski, W. A.; Eff-Darwich, A.; Gough, D. O.; Haber, D. A.; Hoeksema, J. T.; Howe, R.; Korzennik, S. G.; Kosovichev, A. G.; Larsen, R. M.; Pijpers, F. P.; Scherrer, P. H.; Sekii, T.; Tarbell, T. D.; Title, A. M.; Thompson, M. J.; Toomre, J.
Bibliographical reference
The Astrophysical Journal, Volume 505, Issue 1, pp. 390-417.
Advertised on:
9
1998
Journal
Citations
837
Refereed citations
661
Description
The splitting of the frequencies of the global resonant acoustic modes
of the Sun by large-scale flows and rotation permits study of the
variation of angular velocity Omega with both radius and latitude within
the turbulent convection zone and the deeper radiative interior. The
nearly uninterrupted Doppler imaging observations, provided by the Solar
Oscillations Investigation (SOI) using the Michelson Doppler Imager
(MDI) on the Solar and Heliospheric Observatory (SOHO) spacecraft
positioned at the L_1 Lagrangian point in continuous sunlight, yield
oscillation power spectra with very high signal-to-noise ratios that
allow frequency splittings to be determined with exceptional accuracy.
This paper reports on joint helioseismic analyses of solar rotation in
the convection zone and in the outer part of the radiative core.
Inversions have been obtained for a medium-l mode set (involving modes
of angular degree l extending to about 250) obtained from the first 144
day interval of SOI-MDI observations in 1996. Drawing inferences about
the solar internal rotation from the splitting data is a subtle process.
By applying more than one inversion technique to the data, we get some
indication of what are the more robust and less robust features of our
inversion solutions. Here we have used seven different inversion
methods. To test the reliability and sensitivity of these methods, we
have performed a set of controlled experiments utilizing artificial
data. This gives us some confidence in the inferences we can draw from
the real solar data. The inversions of SOI-MDI data have confirmed that
the decrease of Omega with latitude seen at the surface extends with
little radial variation through much of the convection zone, at the base
of which is an adjustment layer, called the tachocline, leading to
nearly uniform rotation deeper in the radiative interior. A prominent
rotational shearing layer in which Omega increases just below the
surface is discernible at low to mid latitudes. Using the new data, we
have also been able to study the solar rotation closer to the poles than
has been achieved in previous investigations. The data have revealed
that the angular velocity is distinctly lower at high latitudes than the
values previously extrapolated from measurements at lower latitudes
based on surface Doppler observations and helioseismology. Furthermore,
we have found some evidence near latitudes of 75 deg of a submerged
polar jet which is rotating more rapidly than its immediate
surroundings. Superposed on the relatively smooth latitudinal variation
in Omega are alternating zonal bands of slightly faster and slower
rotation, each extending some 10 deg to 15 deg in latitude. These
relatively weak banded flows have been followed by inversion to a depth
of about 5% of the solar radius and appear to coincide with the evolving
pattern of ``torsional oscillations'' reported from earlier surface
Doppler studies.