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Questions 1 – 24: Due Wednesday, February 29, 5:00 pm.
Homework #4 Questions 1 – 24: Due Wednesday, February 29, 5:00 pm. Questions 25 & 26: Due now
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What are they and how do we know?
Stars Energy output Sizes Masses Colors Temperatures Lifetimes What are they and how do we know?
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How do we measure stellar temperatures?
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Properties of Thermal (Continuous spectrum) Radiation
Hotter objects emit more light per unit area at all wavelengths. Hotter objects have their peak emission at shorter (bluer) wavelengths.
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Thermal spectra from stars show…
Hottest stars: 50,000 K Coolest stars: 3,000 K Sun’s photosphere is 5,800 K
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Activity involved developing classification scheme for spectra
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Prominence of specific lines were used in initial spectra classification. Spectral types were named A, B, C, D, … A B F G K M O
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Reordering of spectral types in order of decreasing temperature removed some spectral types
B A F G K M
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Absorption lines in a star’s spectrum correspond to a spectral type that reveals its temperature
(Hottest) O B A F G K M (Coolest)
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(Hottest) O B A F G K M (Coolest)
Remembering Spectral Types (Hottest) O B A F G K M (Coolest) Oh, Be A Fine Girl, Kiss Me Only Boys Accepting Feminism Get Kissed Meaningfully
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How do we measure stellar masses?
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The orbit of a binary star system depends on the strength of gravity
I’m not sure where this came from, if it’s not on the CD, let me know. Many stars are in binary systems, where two stars orbit about each other. The orbit of a binary star system depends on the strength of gravity
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Types of Binary Star Systems
Visual Binary Eclipsing Binary Spectroscopic Binary About half of all stars are in binary systems
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We can directly observe the orbital motions of these stars
Visual Binary We can directly observe the orbital motions of these stars
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Eclipsing Binary We can measure periodic eclipses
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Spectroscopic Binary We determine the orbit by measuring Doppler shifts
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We measure mass using gravity
Direct mass measurements are possible only for stars in binary star systems p = period a = average separation 4π2 G (M1 + M2) P2 = a3
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Need 2 out of 3 observables to measure mass:
Orbital Period (P) Orbital Separation (a or r = radius) Orbital Velocity (v) For circular orbits, v = 2pr / P v r M
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Most massive stars: 100 MSun Least massive stars: 0.08 MSun (MSun is the mass of the Sun)
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We have learned that a star is a large, luminous ball of gas and plasma that is massive enough to have the central temperatures and pressures necessary for nuclear fusion to occur.
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But stars have different colors (temperatures) and different luminosities.
How do we explain these differences?
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“Hertzsprung-Russell Diagram”
A convenient way to gain insight into properties and life-cycles of stars is through the most famous and perhaps the most important diagram in astronomy: “Hertzsprung-Russell Diagram”
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Hertzsprung-Russell Diagram: A plot of the temperature, color or spectral type of stars (they are all inter-related) against their luminosity (or its equivalent, absolute magnitude)
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An HR diagram for ~15,000 stars within 100 parsecs (326 light years) of the Sun shows that stars do not fall everywhere in the H-R Diagram, but rather fall into four areas: Main Sequence Giants Supergiants White dwarfs
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Most stars fall somewhere on the main sequence of the H-R diagram
Luminosity (Solar Luminosities) Surface Temperature (K)
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Hot stars (bluer) are found at the upper left hand end of the Main Sequence while cooler (redder) stars are found to the lower right. Luminosity (Solar Luminosities) Surface Temperature (K)
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Large radius Stars with lower T (lower emissions per surface area) and higher L (greater overall brightness) than main-sequence stars must have larger radii: giants and supergiants Luminosity (Solar Luminosities) Surface Temperature (K)
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Stars with higher T (higher emissions per surface area) and lower L (lower overall brightness) than main-sequence stars must have smaller radii: white dwarfs Luminosity (Solar Luminosities) Small radius Surface Temperature (K)
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A star’s full classification includes spectral type (spectral line identities) and luminosity class (line shapes, related to the size of the star): I - supergiant II - bright giant III - giant IV - subgiant V - main sequence Examples: Sun - G2 V Sirius - A1 V Proxima Centauri - M5.5 V Betelgeuse - M2 I
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H-R diagram depicts: Temperature Color Spectral Type Luminosity Radius
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Main-sequence stars are fusing hydrogen into helium in their cores, like the Sun
Luminous main-sequence stars are hot (blue) Less luminous ones are cooler (yellow or red)
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60 M 30 M 10 M Measurements of stellar masses show that hotter (bluer) main sequence stars are much more massive than cooler (redder) main sequence stars 5 M 1 M 0.1 M (1 M = 1 solar mass)
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High-mass stars The mass of a normal, hydrogen-burning star, i.e., a main sequence star, determines its luminosity and spectral type! Low-mass stars
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Core pressure and temperature of a higher-mass star need to be larger in order to balance gravity
Higher core temperature boosts fusion rate, leading to larger luminosity
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Stellar Properties Review
Luminosity: from brightness and distance 10-4 LSun LSun Temperature: from color and spectral type 3,000 K ,000 K Mass: from period (P) and average separation (a) of binary-star orbit 0.08 MSun MSun
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Mass & Lifetime Sun’s life expectancy: 10 billion years
Life expectancy of 10 MSun star: 10 times as much fuel, uses it 104 times as fast 10 million years ~ 10 billion years x 10 / 104 Life expectancy of 0.1 MSun star: 0.1 times as much fuel, uses it 0.01 times as fast 100 billion years ~ 10 billion years x 0.1 / 0.01 Until core hydrogen (10% of total) is used up
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107 yrs Hotter, more massive stars have shorter main sequence lifetimes than cooler, less massive stars 108 yrs 109 yrs 1010 yrs 1011 yrs
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Very rare Observations show that hotter main sequence stars are much less common than cooler main sequence stars. There are two reasons for this: 1) the former have very short lifetimes, 2) more low mass stars are born than high mass stars. Very common
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Main-Sequence Star Summary
High Mass Stars: High Luminosity Short-Lived Rare Large Radius Blue Low Mass Stars: Low Luminosity Long-Lived Common Small Radius Red Main-Sequence Star Summary
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Giants, supergiants, & white dwarfs
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Off the Main Sequence Stellar properties depend on both mass and age: those that have finished fusing H to He in their cores are no longer on the main sequence All stars become larger and redder after exhausting their core hydrogen: giants and supergiants Most stars end up small and white after fusion has ceased: white dwarfs
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We will return to a discussion of giants, supergiants and white dwarfs when we discuss the deaths of stars.
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