Download
1 / 32
320 likes | 442 Views
Studying Binary Stars a Few Photons at a Time. Elliott Horch, CIS. Astronomy. Stars are. very. VERY. VERY. …cool. What do we want to know about stars?. How do they form? How much matter is needed? Are planets involved? How do stars work? Do they change? How long do they live?
E N D
Studying Binary Stars a Few Photons at a Time • Elliott Horch, CIS
Astronomy Stars are very VERY VERY …cool.
What do we want to know about stars? • How do they form? How much matter is needed? Are planets involved? • How do stars work? • Do they change? How long do they live? • Why do they appear in groups sometimes? • What can they tell us about how the Galaxy formed?
What’s going to help us out in answering those questions? • Mass • Luminosity (total light output) • Size (radius) • Surface Temperature • Age • Heavy Metal Content (“metallicity”) • etc.
What do we think we know about stars? • Energy production mechanisms • Basic life cycle features • Pulsation • Spectral features
What still confuses us? • Details, details… (Sigh.) • e.g. how to calibrate luminosities, etc?? • Neutrinos • Formation Processes • “Jumps” in HR diagram • etc.
Masses and the “MLR” • Theory: Mass and luminosity are related. Our favorite star! 0 log(L/Lsun) 0 log(M/Msun)
Binary stars. Gravitation --> orbit. N q N N N N N N N N N N q r q r r r r r r r r r r Why are masses so hard to measure? Okay, well how? Scales? Ha! BUT: need SIZE of orbit, which means we need the distance.
Why are distances so hard to measure? • Parallax Earth
Our Home Galaxy - The Comic Book Version Globular Clusters Disk Bulge Halo
Two “Populations” • Population I: • Disk dwellers • metal rich • Population II: • Halo dwellers • metal poor MLR log(L/Lsun) Pop I 0 Pop II 0 log(M/Msun)
Imaging Binary Stars • That *3$%%^*&$$% Atmosphere!! • Blurs out star images, can’t see both stars distinctly if they’re too close together. • Related to twinkling. • Telescopes and camera systems: the rest of the optical system. • Big telescopes can resolve closer pairs. • Need high-speed cameras to “freeze” the twinkling.
Why the atmosphere is such a bummer... light Atmosphere Ground
At Big Telescopes, Stars “Speckle” integrated image speckle images
At Big Telescopes, Stars “Speckle” integrated image speckle images
Speckling Binary Star t=0.00s t=0.05s t=0.10s t=0.15s
Speckling Binary Star t=0.00s t=0.05s t=0.10s t=0.15s
Speckling Binary Star t=0.00s t=0.05s t=0.10s t=0.15s
A “Close Binary” t=0.00s t=0.05s t=0.10s t=0.15s
A “Close Binary” t=0.00s t=0.05s t=0.10s t=0.15s
A “Close Binary” t=0.00s t=0.05s t=0.10s t=0.15s
We can Beat the Atmosphere!! 1 arcsec speckle analysis long exposure
KPNO The WIYN Telescope Kitt Peak, Arizona
Hipparcos (True) Binaries W98 W97 W99.89 W99.02 W99 H91 C95 H91
Space Telescope FGSs single star signal double star x
FGS will help us study Pop II binaries. Orbits Masses Luminosities Pop II MLR !!!!!!! Better Ages and Distances to Glob. Clusters!!!! A Real FGS Transfer Function arcsec -0.8 0.8 Henry et al. (1999)
Conclusions • Stars are interesting. • Star images taken at big telescopes “speckle.” • Interferometric imaging of binary stars helps us determine their masses and luminosities, which in turn helps us understand how they work. • Speckle imaging from the ground. • Fine Guidance Sensor data from the Hubble Space Telescope.
