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Padova, October 1980. Padova, October 1980 Padova, October 1980.

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Presentation on theme: "Padova, October 1980. Padova, October 1980 Padova, October 1980."— Presentation transcript:

1 Padova, October 1980

2 Padova, October 1980 Padova, October 1980

3 MASS LOSS ROTATION-MIXING BINARY EVOLUTION MAGNETIC EFFECTS Effects of stellar physics on the chemical yields André Maeder Geneva Observatory In collaboration with Georges Meynet

4 What mass loss in pre- supernova stages of massive stars ? The proximity to the Eddington limit is the physical reason for the onset of WR type mass loss Gräfener et al. 2011 Case of WR stars Maeder et al. 2011

5 Eddington Limit     const. const ~ 30 WR mass loss rates are determined by composition changes Maeder et al., A&A 539, A110 (2012) Maeder et al., A&A 539, A110 (2012) For homologous sequences

6 THERE IS AN EXTREME MASS LOSS RATES IN PRE-SN STAGES MASS

7 Mixing vs. mass loss : MASS LOSS : MIXING: shear ~ thermal diffusivity Higher M Higher T Lower  Mass loss and mixing strongly favoured !

8 -1. More fast rotators Confirmed by: Wisniewski & Björkman, 2006 Mokiem et al. 2006 Martayan et al. 2007 Martayan et al. 2010 Maeder, Grebel, Mermilliod 1999 THREE PROPERTIES OF ROTATION AT LOW Z

9 Z=0.004 Z=0.02 - 2. Higher N/C at lower Z MORE MIXING

10 Z=0.02: drastic deacrease for highmasses Z=0.004: more stars reach break-up velocities. Maeder & Meynet, 2001 -3. Low Z stars reach critical rotation  ROTATIONAL MASS LOSS

11 NEW STABILITY CRITERION Maeder et al. A&A, 553, A1 (2013) RICHARDSON CRITERION RAYLEIGH-TAYLOR LEDOUX CRITERION ZAHN ULRICH, KIPPENHAHN Possible damping or amplification of mixing effects ! DUDIS SCHWARZSCHILD STABLE, IF

12 Hunter et al. 2008

13 Maeder, Przybilla, Nieva et al. 2013

14 From VLT- FLAMES survey (Hunter et al. 2009)

15 NGC 3293-034 Ex. of fit of spectra and A DS models calculated by Przybilla with Hunter et al. parameters Maeder, Przybilla, Nieva et al. 2013

16 0 50 100 150 200 250 300 Mg/H is not constant with v sin i ! Maeder, Przybilla, Nieva et al. 2013

17 Be stars SB2 Maeder et al. (2008) Data from Hunter et al (2008) 14 < M/M O < 20

18 BINARIES: Tidally shear induced mixing (TISM) Song, Maeder, Meynet, Huang, Ekström, Granada (2013) Tidal interaction + meridional circulation + shears + horizontal turbulence in binary models (15 M O + 10 M O ) CASE SPIN UP: v ini /v crit =0.2, P orb = 0.9-1.4 d..

19 STRONG MIXING before RLOF !

20 TISM in BINARIES Internal mixing and larger cores  YIELDS Homogeneous before RLOF, for high masses  thus, no RLOF ! Differential rotation at synchronisation If spin up, lot of angular momentum conveyed to the core  GRBs ?

21 External magnetic field ud-Doula & Owocki (2002) Meynet, Eggenberger, Maeder 2011

22 10 M  V ini =200 km s -1 Z=0.014

23 Magnetic coupling coupling-envelope Asteroseismology (KEPLER), red giant KIC 8366339: core rotates only 10 x faster than surface Beck et al. (2012), Additional braking mechanism (Eggenberger et al. 2012) Pulsar models rotate too fast (Heger et al. 2004) Truncation radius: Loss of angular momentum by the core: Maeder & Meynet In prep.

24 MASS LOSS ROTATION-MIXING BINARY EVOLUTION MAGNETIC BRAKING Effects of stellar physics on the chemical yields André Maeder Geneva Observatory Collaboration with Georges Meynet

25 NGC 3293-034 Ex. of fit of spectra and A DS models calculated by Przybilla with Hunter et al. parameters Maeder, Przybilla, Nieva et al. 2013

26

27 Ekström, Meynet, Maeder 2005 At low Z: Large fraction of MS spent at break--up

28 Moderate N-enrichment Initial track ~ homogeneous

29 BINARIES: Tidally shear induced mixing (TISM) Song, Maeder, Meynet, Huang, Ekström, Granada (2013) Tidal interaction + meridional circulation + shears + horizontal turbulence in binary models (15 M  + 10 M  ) CASE SPIN DOWN: v ini /v crit =0.6, P orb = 1.1-1.8 d

30 N/C vs. N/O plot: depends only on nuclear properties, Independent on mass and rotation, ~linear up to 0.6 ( Maeder, Przybilla, Nieva,Meynet et al. 2013) a

31 N/C vs. N/O plot: depends only on nuclear properties, Independent on mass and rotation, ~linear up to 0.6 ( Maeder, Przybilla, Nieva,Meynet et al. 2013) CN-cycle N-cycle

32 From VLT- FLAMES survey (Hunter et al. 2009)

33 Case spin up CASE SPIN UP: v ini /v crit =0.2, P orb = 0.9-1.4 d

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