Constraining the neutrino magnetic dipole moment from white dwarf pulsations

Pulsating white dwarf stars can be used as astrophysical laboratories to constrain the properties of weakly interacting particles. Comparing the cooling rates of these stars with the expected values from theoretical models allows us to search for additional sources of cooling due to the emission of...

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Bibliographic Details
Published in:Journal of cosmology and astroparticle physics 2014-08, Vol.2014 (8), p.54-54
Main Authors: Córsico, A.H., Althaus, L.G., Bertolami, M.M. Miller, Kepler, S.O., García-Berro, E.
Format: Article
Language:English
Subjects:
ASTEROSEISMOLOGICAL CONSTRAINTS
Astronomia i astrofísica
ASTROPHYSICS
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
AXION MASS
AXIONS
Estels nans
Evolution
Física
G117-B15A
INSTABILITY STRIP
LIMITS
LUMINOSITY
MAGNETIC DIPOLE MOMENTS
NEUTRALINOS
neutrino properties
NEUTRINOS
Neutrins
PG-1159 EVOLUTIONARY MODELS
PG-1351+489
PHYSICS
PLASMA
PULSATIONS
stars
Starts
VIRGINIS VARIABLE-STARS
white and brown dwarfs
WHITE DWARF STARS
Àrees temàtiques de la UPC
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Summary:Pulsating white dwarf stars can be used as astrophysical laboratories to constrain the properties of weakly interacting particles. Comparing the cooling rates of these stars with the expected values from theoretical models allows us to search for additional sources of cooling due to the emission of axions, neutralinos, or neutrinos with magnetic dipole moment. In this work, we derive an upper bound to the neutrino magnetic dipole moment (mu(nu)) using an estimate of the rate of period change of the pulsating DB white dwarf star PG 1351+489. We employ state-of-the-art evolutionary and pulsational codes which allow us to perform a detailed asteroseismological period fit based on fully DB white dwarf evolutionary sequences. Plasmon neutrino emission is the dominant cooling mechanism for this class of hot pulsating white dwarfs, and so it is the main contributor to the rate of change of period with time ((Pi) over dot) for the DBV class. Thus, the inclusion of an anomalous neutrino emission through a non-vanishing magnetic dipole moment in these sequences notably influences the evolutionary timescales, and also the expected pulsational properties of the DBV stars. By comparing the theoretical ((Pi) over dot) value with the rate of change of period with time of PG 1351+489, we assess the possible existence of additional cooling by neutrinos with magnetic dipole moment. Our models suggest the existence of some additional cooling in this pulsating DB white dwarf, consistent with a non-zero magnetic dipole moment with an upper limit of mu(nu) less than or similar to 10(-11) mu(B). This bound is somewhat less restrictive than, but still compatible with, other limits inferred from the white dwarf luminosity function or from the color-magnitude diagram of the Globular cluster M5. Further improvements of the measurement of the rate of period change of the dominant pulsation mode of PG 1351+489 will be necessary to confirm our bound. Peer Reviewed
ISSN:1475-7516
1475-7516
DOI:10.1088/1475-7516/2014/08/054