Alex Gianninas Mukremin Kilic, Warren Brown, & J.J. Hermes December 9 th, th Texas Symposium

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Transcription:

Alex Gianninas Mukremin Kilic, Warren Brown, & J.J. Hermes December 9 th, 2013 27th Texas Symposium

White Dwarf Properties M ~ 0.6 M R ~ 0.01 R ~ 1 R ~ 10 6 log g ~ 8.0 (log g = 4.4) T eff ~ 150,000 3000 K No H burning WDs cool over several Gyrs 12/9/2013 Texas Symposium 2

Gianninas et al. (2011) Binary Evolution 12/9/2013 Texas Symposium 3

These friends are binary companions that stripped a significant amount of material from the progenitor, preventing the ignition of He burning, giving birth to an extremely low mass (ELM) WD ELM WDs are found almost exclusively in shortperiod binaries (P < 1 day) Many will merge in less than a Hubble time! 12/9/2013 Texas Symposium 4

ELM Survey Targeted search for Extremely Low Mass WDs ELM WDs = M < 0.25 M Motivation: Progenitors of Type Ia supernovae (DD channel) Progenitors of underluminous supernovae (.Ia SN; Bildsten et al. 2007) Progenitors of AM CVn systems (Kilic et al., 2013) Pulsar companions (e.g. PSR J1816+4510; Kaplan et al. 2013) Nearest systems are important sources of gravitational waves! 12/9/2013 Texas Symposium 5

ELM Survey: Target Selection Hypervelocity Survey (Warren Brown, SAO): search for B type stars leaving the Galaxy, colors similar to ELM WDs 15% of targets are in fact ELM WDs Spectroscopy from the Sloan Digital Sky Survey (SDSS) SDSS colors (u-g, g-r) 12/9/2013 Texas Symposium 6

ELM Survey: Target Selection Brown et al. (2012) 12/9/2013 Texas Symposium 7

ELM Survey: Follow-up MMT (6.5m), FLWO (1.5m), KPNO 4m Radial velocity follow-up to confirm the binary nature of each candidate Once confirmed, we seek to improve our orbital solution by better sampling all phases of the orbit 12/9/2013 Texas Symposium 8

ELM Survey: Success Rate Brown et al. (2010) Kilic et al. (2011) Brown et al. (2012) Kilic et al. (2012) Brown et al. (2013) Paper ELM WD Merger Systems I 12 6 II 4 2 III 7 6 IV 7 5 V 17 6 Before ELM Survey: Only 6 known merger systems (SPY) Shortest known period is P = 1.5 hr ELM Survey has found 8 systems with P < 1.5 hr and 3 with P < 1 hr 12/9/2013 Texas Symposium 9

Orbital Solutions Orbital solutions provide period (P) and velocity semi-amplitude (K) Brown et al. (2013) 12/9/2013 Texas Symposium 10

ELM Survey: Results Super- Chandrasekhar mass systems not necessarily Type Ia progenitors Mass ratio is important 0.2 + 1.2 M systems Stable mass transfer system (AM CVn,.Ia SN) Can be WD+NS binaries Brown et al. (2013) 12/9/2013 Texas Symposium 11

Progenitors of AM CVn (cataclysmic variables, novae) Massive Companion Pulsars? No detections with Chandra Will undergo stable mass transfer Result: AM CVn Kilic et al. (2013) 12/9/2013 Texas Symposium 12

Masses & Radii Model dependent and model independent measurements Model independent: Eclipses Ellipsoidal variations (tidal distortion) Model dependent: two ingredients Precise measurements of the atmospheric parameters (T eff and log g) Evolutionary models (Althaus et al., 2013) 12/9/2013 Texas Symposium 13

Gravitational Wave Strain Gianninas et al. (2014, in prep) Galactic foreground LISA, 1yr, S/N = 5 LISA, 1yr, S/N = 1 12/9/2013 Texas Symposium 14

elisa Replaces LISA Two beams instead of three Reduced sensitivity Frequency range spans four decades (~0.1 mhz ~1 Hz) The Gravitational Universe approved as science theme for ESA L3 project ( launch in ~2034) 12/9/2013 Texas Symposium 15

elisa Verification Sources Amaro-Seoane et al. (2013) 12/9/2013 Texas Symposium 16

J0651 Poster child for ELM WDs Shortest period ELM WD binary P = 12.75 min! Eclipsing! After initial discovery, photometric followup at McDonald, APO, Gemini North and GTC Hermes et al. (2013) 12/9/2013 Texas Symposium 17

Light Curves for J0651 Direct detection of orbital decay! Hermes et al. (2013) 12/9/2013 Texas Symposium 18

O-C Diagram for J0651 12/9/2013 Texas Symposium Hermes et al. (2013) 19

Hulse-Taylor Pulsar PSR B1913+16 30 YEARS! Weisberg & Taylor (2005) 12/9/2013 Texas Symposium 20

Conclusions ELM Survey: targeted search for extremely low-mass WDs Success: ~60 systems with P < 1 day J0651 Rate of orbital decay agrees with GR Only takes a few years to detect Verification source for elisa 12/9/2013 Texas Symposium 21

More to come ELM Survey Ongoing: upcoming observing runs on MMT and KPNO 4m Expand to Southern Hemisphere NEW! : 20-min system discovered! J0651 Continued monitoring 12/9/2013 Texas Symposium 22

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