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The s-process Fe Co Ni Rb Ga Ge Zn Cu Se Br As Zr Y Sr Kr (n,  ) ()() ()() r-process p-process 63 Ni, t 1/2 =100 a 64 Cu, t 1/2 =12 h, 40 % (

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Presentation on theme: "The s-process Fe Co Ni Rb Ga Ge Zn Cu Se Br As Zr Y Sr Kr (n,  ) ()() ()() r-process p-process 63 Ni, t 1/2 =100 a 64 Cu, t 1/2 =12 h, 40 % ("— Presentation transcript:

1 the s-process Fe Co Ni Rb Ga Ge Zn Cu Se Br As Zr Y Sr Kr (n,  ) ()() ()() r-process p-process 63 Ni, t 1/2 =100 a 64 Cu, t 1/2 =12 h, 40 % (   ), 60 % (   ) 79 Se, t 1/2 =65 ka 80 Br, t 1/2 =17 min, 92 % (   ), 8 % (   ) 85 Kr, t 1/2 =11 a r-only p-only s-only neutron number proton number (from Rene Reifarth)

2 The sites of the s-process weak s-process: core He/ shell C burning in massive stars main s-process: He shell flashes in low mass TP-AGB stars approx. steady flow can easily interpolate s-contribution for s+r-nuclei if neutron capture cross sections are known

3 The weak s-process Site: Core He burning (and shell C-burning) in massive stars (e.g. 25 solar masses) He burning core contains initially 14 N 14N 18O 22Ne  capture  14 N is rapidly converted to 22 Ne Towards the end of He burning T~3e8 K: 22 Ne( ,n) provides a neutron source preexisting Fe (and other nuclei) serve as seed for a (secondary) s-process

4 Typical conditions (Raiteri et al. ApJ367 (1991) 228 and ApJ371(1991)665: Temperature2.2 - 3.5 e8 K Density1 - 3e3 g/cm 3 Average neutron density7e5 cm -3 Peak neutron density2e7 cm -3 Neutron exposure    0.206 / mb * ) time integrated neutron flux Results: produced abundance/solar

5 The main s-process Site: low mass TP-AGB stars ( thermally pulsing stars on the asymptotic giant branch in the HR diagram, 1.5 - 3 solar masses ) CO core H-burning shell He-burning shell unstable - burns in flashes (thin shell instability)

6 He flash (thermal pulse) H burning shell 13C pocket H/He burning in a TP-AGB star number of He flashes in stars life: few – 100 period of flashes: 1000 – 100,000 years 160 yr 52,000 yr 40 yr (Lugaro et al. ApJ586(2003)1305) s-process in: He flash via 22 Ne( ,n) 13 C pocket via 13 C( ,n)

7 13 C( ,n) in pocket 22 Ne( ,n) in He flash Temperature0.9 x 10 8 K2.7 x 10 8 K Neutron density7 x 10 7 cm -3 10 10 cm -3 Duration20,000 yrfew years Neutron exposure    0.1 / mb0.01 / mb Conditions during the main s-process weaker but longer main contribution (90% of exposure) short, intense burst slight modification of abundances (branchings !)

8 Results for main s-process model (Arlandini et al. ApJ525 (1999) 886) = s-only

9 The p-process produces p-rich, usually rare (0.1-1% isotopic fraction), stable isotopes Site: Supernova shock passing through O-Ne layers of progenitor star Conditions at different locations in O/Ne layers during a Supernova: (Rayet et al. A&A298 (1995) 517)

10 p-process mechanism Secondary process. Seed: previous s-process in low mass star) Series of ( ,n) ( ,p) ( ,  ) photodisintegration reactions (also called  -process) s nucleus p nucleus produces eventually lighter p-nuclei ( ,n) ( ,p) ( ,n) produced by disintegration of heavier nuclei

11 p-process path Rayet et al. A&A227(1990)271 p-nuclei ( ,n) flow stopped by (n,  ) flow proceeds via ( ,p) or ( ,  )

12 p-process model results (Rayet et al. A&A298 (1995) 517) Mo-Ru underproduction problem (1-10% isotopic fraction !)


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