pulsations in white dwarfs g. fontaine université de montréal collaborators: p. brassard, p....
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Pulsations in White Dwarfs
G. Fontaine
Université de Montréal
Collaborators:
P. Brassard, P. Bergeron, P. Dufour, N. Giammichele (U. Montréal)
S. Charpinet (U. Toulouse)
S. Randall (ESO, Garching)
V. Van Grootel (U. Liège)
ZZ Cet stars
H-atmosphere (DA) white dwarfs (direct descendants of ~80% of post-AGB objects)
Low-degree (1,2), low- to mid-order g-mode pulsators
Opacity-driven (convective driving) due to recombination of H in the envelope
V777 Her stars
He-atmosphere (DB) white dwarfs (cool descendants of ~20% of post-AGB objects)
Low-degree (1,2), low- to mid-order g-mode pulsators
Opacity-driven (convective driving) due to recombination of He in the envelope
GW Vir stars
Mixed-atmosphere (PG1159) white dwarfs (immediate, very hot descendants of ~20% of post-AGB objects; He-C-O in roughly comparable proportions)
Low-degree (1,2), low- to mid-order g-mode pulsators
Opacity-driven (classical kappa-mechanism) due to opaque high ions of C and O in the envelope
Hot DQV stars
Extremely rare (14 / 25,000) carbon-atmosphere white dwarfs discovered in 2007 only. They bunch around Teff~20,000 K and have very high surface gravities. They are likely all highly magnetic (>1 MGauss) and half them pulsate.
Low-degree (1,2), low- to mid-order g-mode pulsators
Opacity-driven (convective driving) due to recombination of C in the envelope
ELM DAV
Rare, extremely low mass DA white dwarfs produced by common envelope evolution (post-RGB remnants)
Presumably low-degree (1,2), low- to mid-order g-mode pulsators discovered in 2012
ELM DAV
Rare, extremely low mass DA white dwarfs produced by common envelope evolution (post-RGB remnants)
Presumably low-degree (1,2), low- to mid-order g-mode pulsators discovered in 2012
Hot DAV stars
DA white dwarfs with very thin H envelopes. “DB’s disguised as DA’s”
Presumably low-degree (1,2), low- to mid-order g-mode pulsators
Presumably opacity-driven (kappa-mechanism or convective driving) due to recombination of He in the envelope
Hot DAV stars
DA white dwarfs with very thin H envelopes. “DB’s disguised as DA’s”
Presumably low-degree (1,2), low- to mid-order g-mode pulsators
Presumably opacity-driven (kappa-mechanism or convective driving) due to recombination of He in the envelope
DAOV stars
Low-mass, post-EHB DA stars predicted to pulsate
Low-degree (1,2), very low-order g-mode pulsators
Epsilon-mechanism due to H-shell burning at base of the H envelope
DAOV stars
Low-mass, post-EHB DA stars predicted to pulsate
Low-degree (1,2), very low-order g-mode pulsators
Epsilon-mechanism due to H-shell burning at base of the H envelope
Recent highlights in white dwarf seismology
1) An enlightening review
Recent highlights in white dwarf seismology
2) Internal rotation profile and total angular momentum
Map of the internal rotation profile of PG 1159-035, the prototype of the GW Vir class of pulsating white dwarfs
Recent highlights in white dwarf seismology
3) An updated view of the ZZ Ceti instability strip
Recent highlights in white dwarf seismology
4) Discovery of the 2nd pulsating star massive enough to be partly solidified in its core (a ZZ Ceti star)
Recent highlights in white dwarf seismology
5) Finally making sense of the GW Vir instability strip
Evolution of the predicted spectrum of excited dipole modes in an evolving model with a fixed PG1159 envelope composition (red dots), and that of a model in which stellar winds and gravitational settling are taken into account (black dots). The latter suggests that a GW Vir star (PG1159 spectral type) should again pulsate in its lifetime but, this time, as a much cooler DB white dwarf of the V777 Her type.
dipole mode period spectrum,
n=1,38, early phases n=1,30, later phases
excited modes
blue edge
degeneracy boundary
base of atmosphere tau=100
Range of depth of
interest for driving by κ-mechanism
The ZZ Ceti instability strip
extended into the ELM regimePredicted spectrum of excited
dipole modes with TDC
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