The influence of internal magnetic layers on the frequencies of solar p-modes

C  Foullon; B  Roberts

doi:10.1051/0004-6361:20041910

The influence of internal magnetic layers on the frequencies of solar p-modes

C Foullon, B Roberts

Applied Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

Buried magnetic fields at the base of the convection zone and in the anchoring zones of sunspots are presumed to vary over the solar activity cycle. Their effect on p-mode oscillations is explored in detail, through theoretical modelling. The helioseismic signature from a "tachocline" or " shallow" horizontal layer of magnetic field, buried in a plane-stratified model of the Sun, is explored by examining frequency shifts of various order and degree. p- modes propagating perpendicular to the magnetic field lines are found to yield the largest frequency shifts. However, frequency shifts due to buried magnetic fields are considerably smaller than observationally determined shifts over the solar cycle. Nonetheless, an analytical approach to the problem provides useful insight for solar and stellar applications.

Original language	English
Pages (from-to)	713
Number of pages	18
Journal	Experimental Astronomy
Volume	439
DOIs	https://doi.org/10.1051/0004-6361:20041910
Publication status	Published - Aug 2005

Keywords

Sun : helioseismology
Sun : interior
Sun : magnetic fields
Sun : oscillations
CONVECTION ZONE
FLUX TUBES
DIFFERENTIAL ROTATION
F-MODES
CYCLE
FIELD
WAVES
OSCILLATIONS
HELIOSEISMOLOGY
ATMOSPHERE

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10.1051/0004-6361:20041910

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title = "The influence of internal magnetic layers on the frequencies of solar p-modes",

abstract = "Buried magnetic fields at the base of the convection zone and in the anchoring zones of sunspots are presumed to vary over the solar activity cycle. Their effect on p-mode oscillations is explored in detail, through theoretical modelling. The helioseismic signature from a {"}tachocline{"} or {"} shallow{"} horizontal layer of magnetic field, buried in a plane-stratified model of the Sun, is explored by examining frequency shifts of various order and degree. p- modes propagating perpendicular to the magnetic field lines are found to yield the largest frequency shifts. However, frequency shifts due to buried magnetic fields are considerably smaller than observationally determined shifts over the solar cycle. Nonetheless, an analytical approach to the problem provides useful insight for solar and stellar applications.",

keywords = "Sun : helioseismology, Sun : interior, Sun : magnetic fields, Sun : oscillations, CONVECTION ZONE, FLUX TUBES, DIFFERENTIAL ROTATION, F-MODES, CYCLE, FIELD, WAVES, OSCILLATIONS, HELIOSEISMOLOGY, ATMOSPHERE",

author = "C Foullon and B Roberts",

year = "2005",

month = aug,

doi = "10.1051/0004-6361:20041910",

language = "English",

volume = "439",

pages = "713",

journal = "Experimental Astronomy",

publisher = "Springer",

}

TY - JOUR

T1 - The influence of internal magnetic layers on the frequencies of solar p-modes

AU - Foullon, C

AU - Roberts, B

PY - 2005/8

Y1 - 2005/8

N2 - Buried magnetic fields at the base of the convection zone and in the anchoring zones of sunspots are presumed to vary over the solar activity cycle. Their effect on p-mode oscillations is explored in detail, through theoretical modelling. The helioseismic signature from a "tachocline" or " shallow" horizontal layer of magnetic field, buried in a plane-stratified model of the Sun, is explored by examining frequency shifts of various order and degree. p- modes propagating perpendicular to the magnetic field lines are found to yield the largest frequency shifts. However, frequency shifts due to buried magnetic fields are considerably smaller than observationally determined shifts over the solar cycle. Nonetheless, an analytical approach to the problem provides useful insight for solar and stellar applications.

AB - Buried magnetic fields at the base of the convection zone and in the anchoring zones of sunspots are presumed to vary over the solar activity cycle. Their effect on p-mode oscillations is explored in detail, through theoretical modelling. The helioseismic signature from a "tachocline" or " shallow" horizontal layer of magnetic field, buried in a plane-stratified model of the Sun, is explored by examining frequency shifts of various order and degree. p- modes propagating perpendicular to the magnetic field lines are found to yield the largest frequency shifts. However, frequency shifts due to buried magnetic fields are considerably smaller than observationally determined shifts over the solar cycle. Nonetheless, an analytical approach to the problem provides useful insight for solar and stellar applications.

KW - Sun : helioseismology

KW - Sun : interior

KW - Sun : magnetic fields

KW - Sun : oscillations

KW - CONVECTION ZONE

KW - FLUX TUBES

KW - DIFFERENTIAL ROTATION

KW - F-MODES

KW - CYCLE

KW - FIELD

KW - WAVES

KW - OSCILLATIONS

KW - HELIOSEISMOLOGY

KW - ATMOSPHERE

U2 - 10.1051/0004-6361:20041910

DO - 10.1051/0004-6361:20041910

M3 - Article

VL - 439

SP - 713

JO - Experimental Astronomy

JF - Experimental Astronomy

ER -

The influence of internal magnetic layers on the frequencies of solar p-modes

Abstract

Keywords

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