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Birth of Stars. p. 216. Properties of stars: Mass Luminosity (Intrinsic brightness) Surface temperature Size (radius) Composition Distance from us is NOT a property of the star. Luminosity : the brightness of a star as we see it depends on the
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Birth of Stars p. 216
Properties of stars: Mass Luminosity (Intrinsic brightness) Surface temperature Size (radius) Composition Distance from us is NOT a property of the star. Luminosity: the brightness of a star as we see it depends on the intrinsic brightness (luminosity measured as energy per unit time) and distance from us. Luminosity (L) = 4πR²×brightness. L = 4πR²σT4. Where R is radius of the star and T is temperature in Kelvin. σ is a constant. The luminosity of a star is normally expressed in units of the luminosity of the Sun.
Stars are born – protostars Middle age – main sequence stars Death – White dwarf or Supernova Life cycle of a star
The brightness (magnitude) of a star depends on the star luminosity (intrinsic brightness) and the distance from us. For all practical purposes, stars (except the Sun) are so far away that all we observe is a point source. Brightness of a star
Spectra Fig. 11-1, p.218
Continuous spectra of stars λmax(nm)= 2,900,000/T (ºK) Fig. 11-2, p.218
Emission spectra of Hydrogen Fig. 11-3, p.219
Spectral types Fig. 11-5, p.220
Distance (d) by parallax method d = 1 / p If p in arc sec Then d is in parsec 1 parsec = 3.26ly Fig. 11-7, p.221
Intensity α 1/R² Fig. 11-9, p.223
Luminosity L = 4πR²σT4. Size and temperature! I.e. If temperature is twice the L is 16 times higher. Absolute Magnitude M same as apparent magnitude m at 10 parsec = 32.6 ly. m – M = -5 + 5log 10 (d/3.26). D in ly. If two of the quantities are known, the third can be computed. Sun: m = -27, M = 5. Sirius: m = -1.5, M = +1.5. d = 9 ly. Spica: m = +1, M = - 4. d = 262 ly. Star Luminosity and absolute magnitude
H R Diagram Bright Dim Hot Cool Fig. 11-13, p.227
Star masses determined from double stars. About half the stars are in groups of two or more stars. Stellar sizes measured directly from eclipsing binaries. There are about 2,000 eclipsing binaries. Stellar size can also be computed from luminosity. Star Mass and Size
Double star Albireo, also known as Cygni, contains a B star and a K star. Beautiful pair because of their contrasting colors. Fig. 11-17, p.230
Two stars revolving around each other And moving in space. MA + MB = R³/ P² Where M is in solar mass units, P in years and R in AU Fig. 11-22, p.233
Doppler shift due to motion Fig. 11-16, p.230
Eclipsing binary measure mass and diameter About 2,000 eclipsing binaries Fig. 11-20, p.232
Plots of luminosity, radius,temperature vs mass for main sequence stars
Variable stars • Light intensity varies with time. • RR Lyra: Period 6 to 12 hours. Absolute magnitude about 0.5. • Cepheid variable stars: Period from 1 to 50 days. Absolute magnitude related to period.
Cepheid variable star Fig. 11-26, p.236
Period determines the absolute magnitude M. Apparent magnitude (m) is measured (how bright it looks to us). m – M = -5 + 5log 10 (d/3.26). D in ly. Distance d is computed as two of the three variables are known. In a cluster of stars, or even in a galaxy, only one variable star is needed to calculate the distance. Variable stars to determine distance
Open cluster of stars in the constellation Carina. Fig. 11-29, p.238
Open cluster, surrounded by the Rosette Nebula Fig. 11-30, p.238
Globular cluster M15 in the constellation Pegasus. Has a massive Black hole in the Center. Fig. 11-31, p.238
The vast majority of stars are main sequence. The most important quantity is mass. The larger the mass; The higher the surface temperature. The larger the size (diameter). The brighter the star. The shorter the lifetime. Main Sequence Stars
Temperature: 3,000ºK to 50,000ºK; Sun 5,800ºK Mass: 0.08 to 80 times mass of Sun. Size: 0.01 to 1,000 times diameter of Sun. Luminosity: 10-4 to 10+6 times the Sun. Composition (by number): 92% hydrogen, 8% helium and <<1% other heavier elements. Main sequence stars
H-R Diagram Fig. 11-32, p.239
Double cluster in Perseus, Fig. 11-33, p.240
M<0.08 .08<M<0.4 0.4<M<1.4 1.4<M<~4 M>~4 P R O T O S T A R | M a i n S e q u e n c e | R E D G I A N T | | | Planetary Supernova | | | Nebula | | W h i t e D w a r f | B r o w n D w a rf Neutron Star OR Black Hole Stellar Evolution M A I N S E Q U E N C E R E D G I A N T W H I T E D W A R F B R O W N D W A R F