Post on 03-Sep-2018
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Gravitational waves from double whitedwarfs and AM CVn binaries
Gijs NelemansInstitute of Astronomy, Cambridge
Simon Portegies ZwartAmsterdamLev YungelsonMoscowFrank VerbuntUtrecht
Outline
� Introduction: double white dwarfs and AM CVnsystems as GWR sources
� A model for the double white dwarf and AM CVnpopulation and their GWR signal
� New double white dwarf observations, the SPYproject
� New AM CVn observations: short period systems
� Update on LISA sources: resolved double whitedwarf and AM CVn systems
� Conclusions
Gijs Nelemans
Introduction: GWR from binary white dwarfs
� Most stars become white dwarfs and many arepart of (close) binary system
� Theoretical expectation is lots of close double whitedwarfs
� After GWR brings them together, stable mass trans-fer may ensue; AM CVn systems
� Observational problem: they are faint
� Close double white dwarfs and AM CVn systemsare low-frequency gravitational wave sources
� Double white dwarfs are so numerous that theyform an unresolved noise for LISA, most AM CVnsystems are very weak and don’t add to the noise.
Gijs Nelemans
A model for the double white dwarf andAM CVn population and their GWR signal
� Population synthesis for double white dwarfs andAM CVn systemsNelemans et al. 2001, A&A, 365, 491 and 368, 939
� Large uncertainty for AM CVn systems: direct im-pact accretion for initial phases mass transfer
� Limited comparison to observations: reasonableagreement
� Model for the Galactic distribution of stars
� Gravitational waves from (all) compact binariesNelemans et al. 2001, A&A, 375, 890
Gijs Nelemans
‘‘Observable’’ double w
hite dwarf population
Nelemans, Yungelson, Portegies Zwart, Verbunt 2001, A&A, 365, 491
GW
R signal of G
alactic double white dw
arfs
Nelemans, Yungelson, Portegies Zwart, 2001, A&A, 375, 890
New double white dwarf observations,the SPY project
� � 15 were known
� ESO VLT survey of � 1500 white dwarfs for radialvelocity variations (PI Napiwotzki)
� Current status:
– Surveyed 497 white dwarfs
– 94 with radial velocity variations� 80 with white dwarf companion� 14 with main sequence companion
– 9 double lined systems (see both white dwarfs)
– 5 already have period determinationsbetween 0.3 and 1.5 d
Gijs Nelemans
New AM CVn observations:short period systems
� Three new (possible) AM CVn systems(7 were known)
� V407 Vul (RX J1914.4+2456)
– P = 9.5 min, X-ray source,“No lines” spectrumDirect impact?Cropper et al. 1998, Ramsay et al. 2002, Mash & Steeghs 2002
� KUV 01584-0939
– P = 10.3 min, previously classified as Cata-clysmic VariableWarner & Woudt, 2002
� RX J0806.3+1527
– P = 5.3 min, X-ray source,He(+H?) emission line spectrumDirect impact?Israel et al. 2002, Ramsay et al. 2002
Gijs Nelemans
Update on LISA sources: resolved doublewhite dwarfs and AM CVn systems
� AM CVns do not contribute (much) to confusionlimited noise
� However, many AM CVn systems might be re-solved.
� Point mass approximation?
� Resolved systems:
Type resolved systems(wd, wd) 7171�wd, wd) 14225
(ns, wd) 19(ns, ns) 3(bh, wd) 0(bh, ns) 0total 21421
Gijs Nelemans
HP LibAM CVn
V407 VulKUV 01584
RX J0806
Resolved double w
hite dwarfs and A
M C
Vns
Nelemans et al. in preparation
Conclusions
� Models of double white dwarf and AM CVn popu-lation agree qualitatively with observations
� New observations will lead to quantitative test ofmodels
� New short period AM CVn systems are “guaran-teed” LISA sources
� LISA will resolve thousands of double white dwarfsand AM CVn systems and a few neutron star sys-tems
Gijs Nelemans