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Composition and Mass Loss. 2 Two of the major items which can affect stellar evolution are Composition: The most important variable is Y – the helium.

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Presentation on theme: "Composition and Mass Loss. 2 Two of the major items which can affect stellar evolution are Composition: The most important variable is Y – the helium."— Presentation transcript:

1 Composition and Mass Loss

2 2 Two of the major items which can affect stellar evolution are Composition: The most important variable is Y – the helium content Mass Loss: core evolution is essentially independent of envelope evolution especially during later phases. This means that “lower” mass stars can have a “high” luminosity.

3 3Composition and Mass Loss Composition Where this is of greatest impact is in the lifetimes of Pop II/III stars In Pop II (Z ~ 0) t  10 2X and since X is somewhat larger than in Pop I one gets a longer lifetime. In Pop II (Z ~ 0) t  10 2X and since X is somewhat larger than in Pop I one gets a longer lifetime. The converse is that He rich stars leave the MS very quickly. The converse is that He rich stars leave the MS very quickly. Y changes from 0.3 → 0.2 (at Z = 0.03) Y changes from 0.3 → 0.2 (at Z = 0.03) At 5 M  T eff decreases 10% and L decreases by a factor of 2 At 5 M  T eff decreases 10% and L decreases by a factor of 2 Y is the more important

4 4Composition and Mass Loss Heavy Metal Effects Changes in Z lead to evolutionary changes essentially opposite to those in Y but are smaller. Z decreases : L and T eff increase Z decreases : L and T eff increase This means Pop II stars should be more luminous and hotter than Pop I ( at the same X,Y) This is for the Main Sequence

5 5Composition and Mass Loss Post-MS Composition Effects Y is more important than Z for fixing the luminosity As a star evolves Z becomes more important as the energy generation involves Z (CNO dominates in higher mass stars, if there is CNO) The T eff position of the red giant branch is insensitive to Y or Z but the luminosity varies by a factor of 4 according to Y/Z

6 6Composition and Mass Loss A Problem: Convective Mixing There is “no” good ab initio theory of convection Mixing length: defined as some fraction of the pressure scale height General number used is 1.5

7 7Composition and Mass Loss Mass Loss Solar Mass Loss – The solar wind Flux = 10 p / cm 3 with V = 400 km/s Flux = 10 p / cm 3 with V = 400 km/s V must be greater than V esc V must be greater than V esc Solar V esc = SQRT(2GM/R) = 620 km/s at R  and 42 km/s at 1 AU. Current Solar Mass Loss Rate is about 10 -14 M  /year Integrated Mass Loss 10 -4 M  if the rate has been constant. Integrated Mass Loss 10 -4 M  if the rate has been constant. Observed Rates are up to 10 -4 M  / year and are mass dependent.

8 8Composition and Mass Loss P Cygni Stars

9 9Composition and Mass Loss Gamma Cas

10 10Composition and Mass Loss What Does Mass Loss Do To Stellar Evolution? Let us consider two stars with identical composition and the same current mass: Star 1: Constant Mass Star 1: Constant Mass Star 2: dM/dt = -a M  / year Star 2: dM/dt = -a M  / year Obviously Star 2 at t = 0 was more massive than Star 1  It evolved faster. Assumptions: Both convert equal H to He Both convert equal H to He Equal amounts of radiation (energy) produced. Equal amounts of radiation (energy) produced.

11 11Composition and Mass Loss How Do We Proceed? Assume L ~ M α (This is reasonable – α is about 3 to 3.2) Note that M α T is just the total energy produced. T = age of constant mass star T = age of constant mass star T' = age of star with mass loss rate dM/dt T' = age of star with mass loss rate dM/dt Assuming the M(t) is known one can solve for T' given M 2, α, and T.

12 12Composition and Mass Loss What Happens? The sensitivity of the track to the mass loss rate depends on the initial mass: Higher mass stars can sustain a somewhat higher rate without changing the evolution. Higher mass stars can sustain a somewhat higher rate without changing the evolution. The integrated mass loss as a fraction of the total mass is comparable. The integrated mass loss as a fraction of the total mass is comparable. Mass loss of 10 -12 M  or less have little effect on M ~ 1 M  Mass loss of 10 -12 M  or less have little effect on M ~ 1 M  Mass loss of 10 -9 M  or less have little effect on M ~ 5 M  Mass loss of 10 -9 M  or less have little effect on M ~ 5 M  a parameterizes the mass loss

13 13Composition and Mass Loss Rates That Matter For a 1 M  star 10 -10 M  / year will halve the MS lifetime Original mass of 1.4 M  Original mass of 1.4 M  For a 5 M  star 10 -6 M  / year will decimate (10%) the MS lifetime Original mass of 12 M  Original mass of 12 M  Note that the lifetime goes with the original mass as it sets the energy generation.

14 14Composition and Mass Loss Ramifications Globular Clusters: If they are loosing mass then the age estimates are too large Measured mass loss rates are variable Measured mass loss rates are variable The age of the Universe anyone? The age of the Universe anyone?

15 15Composition and Mass Loss Planetary Nebulae Stars “blow off” mass in shells – planetary nebulae are the result of these episodes. Composition reflects extensive processing. C and O enriched C and O enriched Advanced evolutionary stage (post He burning) Advanced evolutionary stage (post He burning) Thought to be post/during ascent to 2 nd Giant Branch. (Detach the shell during an envelope expansion phase) Alternate mechanism is the hyperwind model associated with the AGB stars of low mass.

16 16Composition and Mass Loss PN Typical Shell Mass is 0.01 M . Lifetime is about 50000 years expansion leads to lowering of density until the material becomes some optically thin it cannot detected expansion leads to lowering of density until the material becomes some optically thin it cannot detected Core star is usually very blue - probably the core of an ex-red giant – T eff 50000 - 100000K PN are binary systems in many cases.

17 17Composition and Mass Loss Stellar Mass and the Final Stage of Evolution Chandraskhar Limit: 1.41 M  Electron Degeneracy support Electron Degeneracy support Observed white dwarfs in Pleiades and Hyades Observed white dwarfs in Pleiades and Hyades Turn-off masses are 4 - 6 M  This means the original masses were in excess of 4 - 6 M  they had to lose sufficient mass to get down to the Chandrasekhar limit.

18 18Composition and Mass Loss Close Binaries Generally stellar evolution does not take into account close binaries: Wide system P > years and the stars evolve without interacting Wide system P > years and the stars evolve without interacting Close Systems Mass exchange through the LaGrange points Mass exchange through the LaGrange points Fill Roche lobe, push mass through and dump on the secondary Secondary then heats up and becomes the primary – these are Algol systems Barium and subgiant CH stars Cataclysmic Variables

19 19Composition and Mass Loss Fate of Stars Category Mass Limits M  Fractional Mass of Galaxy Fate a  1.5 0.6WD b 1.5  M  4 0.2WD c 4  M  8 0.06WD/NS d > 8 0.14SN(NS)

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