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Stellar alchemy. • Energy s ources • Nuclear energy • Nuclear reactions in stars • Internal structure of stars. Energy sources. Age of the Sun Solar luminosity ~ 4 × 10 26 W All electric plants together ~ 2 × 10 12 W Conservation of energy → search for the solar energy source
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Stellar alchemy • Energy sources • Nuclear energy • Nuclear reactions in stars • Internal structure of stars
Energy sources Age of the Sun Solar luminosity ~ 4 × 1026 W All electric plants together ~ 2 × 1012 W Conservation of energy → search for the solar energy source (1860s) Hermann von Helmholtz William Thomson, Lord Kelvin
Energy sources - 2 Chemical energy M~ 2 × 1030 kg If Sun made of coal → lifetime ~ 5000 ans→ ± compatible with Bible (Genesis ~ 4000 B.C.) But Darwin’s theory of species evolution through natural selection requires at least hundreds of millions of years → search for other energy sources Charles Darwin
Energy sources - 3 Gravitational energy Contraction of the Sun: requires a few dozen meters per year Contraction from the orbit of Mercury to the actual radius → age ~ 30 millions years → hardly compatible with evolution of species → Kelvin criticizes Darwin’s theory End of the Century: geologists estimate age of Earth to be at least 700 millions years → gravitational contraction insufficient
Energy sources - 4 Mass – energy equivalence 1905: Einstein discovers the equivalence of mass and energy → potential age reaches several billion years → energy stock amply enough → no more age problem But new question: by which mechanism do the Sun (and other stars) transform mass into energy? Albert Einstein
Nuclear energy The atomic nucleus : atom with a nucleus made of Z protons and (A−Z) neutrons Z = atomic number (determines type of atom and chemical properties) A = mass number = number of nucleons (determines isotope) Ex: : main isotope of lithium (3p, 4n) Protons: positive electrical charge Neutrons: no electrical charge → electrostatic repulsion between protons Nucleons bound by strong nuclear force (very intense but short range)
ΔE/A 56Fe 1H A Nuclear energy - 2 Mass defect Mass of nucleus < sum of masses of nucleons Difference = mass defect↔ binding energy: Δm = ΔE/c2 Binding energy per nucleus: • increases from 1H to 56Fe • decreases beyond 56Fe Energy release by: • fission of heavy nuclei • fusion of light nuclei (accompanied by transmutation of neutrons into protons)
Nuclear energy - 3 Solar lifetime M≈ 2 × 1030 kg Composed essentially of hydrogen 1H (~90% in number of atoms) Nuclear fusion: 4 1H → 4He + energy MHe = 3.9726 MH→ ΔM = 0.0274 / 4 per 1H nucleus → ΔE ≈6 × 1014 J/kg The Sun is able to convert ~10% of its hydrogen into helium: → ΔE ≈0.1 × 6 × 1014 × 2 × 1030 ≈ 1044 J → Δt ≈ΔE / L ≈ 1044 / 4 × 1026 ≈ 3 × 1017 s ≈ 10 billion years
Nuclear energy - 3 Stability of nuclei A given atom can have several isotopes Stable isotopes have a number of neutrons: • ≈ equal to the number of protons (light nuclei): N = A−Z ≈ Z • in excess of the number of protons (heavy nuclei): N = A−Z > Z They follow the valley of stability in the N,Z diagram Valley of stability
Nuclear energy - 4 Natural radioactivity 1896: Becquerel fortuitously discovers natural radioactivity Several processes are identified: β−process corresponds to the emission of an e−by the nucleus, accompanied by transmutation of a neutron into a proton It concerns isotopes above the valley of stability (excess of neutrons) β+process corresponds to the emission of a e+ (positon) by the nucleus (isotopes with excess of protons) Henri Becquerel
Nuclear energy - 5 Natural radioactivity The αprocess corresponds to the emission of a helium 4 nucleus The remaining nucleus is generally left in an excited state It gets back to the fundamental state, of minimum energy, by emitting a high energy photon (γ ray) Marie Curie
Nuclear reactions in stars The proton–proton chain The simultaneous encounter of 4 protons is highly improbable → fusion of hydrogen into helium proceeds by steps (1) 1H + 1H → 2H + e+ + ν (Δt ~ 109 years) ν = neutrino • chargeless particle (and massless?) • necessary to ensure conservation of energy and momentum
Nuclear reactions in stars - 2 The proton–proton chain One could have: 2H + 2H → 4He + γ But 1H is much more numerous than 2H and the dominant reaction is (2) 2H + 1H → 3He + γ(Δt ~ 1 s) One could have: 3He + 1H → 4He + e+ +… but it does not work (3) 3He + 3He → 6Be (Δt ~ 106 years) (3′) 6Be → 4He + 2 1H The reaction rate is dominated by the slowest step, here (1)
coulombian repulsion (1/r) U E 0 strong interaction r Nuclear reactions in stars - 3 The proton–proton chain The pp chain needs a temperature T > 107 K in order for protons to be able to overcome the coulombian repulsion and fuse This is eased by a quantum effect: the tunneleffect (wavefunction → nonzero probability to cross a potential barrier) The pp chain is the dominant reaction in the solar core (T ~ 15 × 106 K) It has some variants (pp2 and pp3) that differ in the last qteps
Nuclear reactions in stars - 4 The CNO cycle At temperatures T > 15 × 106 K, hydrogen can fuse into helium following a reaction cycle that uses carbon nuclei already present in the star (products of preceding generations) 12C + 1H → 13N + γ 13N → 13C + e+ + ν 13C + 1H → 14N + γ 14N + 1H → 15O + γ 15O → 15N + e+ + ν 15N + 1H → 12C + 4He (≈ 10% of solar energy)
Nuclear reactions in stars - 5 The triple alpha process Fusion of heavier nuclei requires higher temperatures to overcome the Coulomb repulsive force → core of more massive stars If T > 108 K: fusion of helium into carbon 4He + 4He → 8Be + γ 8Be is highly unstable: 8Be → 4He + 4He in 10−16 s However, from time to time, it will collide before disintegrating 8Be + 4He → 12C + γ → production of carbon, which is the basis of life on Earth
Nuclear reactions in stars - 6 Alpha captures by carbon and oxygen At temperatures allowing fusion of helium into carbon, carbon nuclei can also capture an α particle: 12C + 4He → 16O + γ Oxygen itself can also capture an α particle: 16O + 4He → 20Ne + γ As Z increases, higher and higher temperatures are necessary to overcome the Coulomb barrier In stars similar to the Sun, nuclear fusion stops here In stars of more than 8 M , additional reactions follow
Nuclear reactions in stars - 7 Combustion of carbon and oxygen If T ~ 6 × 108 K: 12C + 12C → 20Ne + 4He 12C + 12C → 23Na + 1H 12C + 12C → 24Mg + γ + other reactions, some of them endothermal If T > 109 K: 16O + 16O → 28Si + 4He 16O + 16O → 31P + 1H 16O + 16O → 31S + n + other reactions, some of them endothermal
Nuclear reactions in stars - 8 Combustion of silicon If T > 3 × 109 K: 28Si + 4He + 4He + 4He … → 56Fe 56Fe = most stable nucleus → the star cannot produce energy by fusion of Fe with other nuclei → reactions producing elements heavier than iron participate to nucleosynthesis but not to energy production
Nuclear reactions in stars - 9 Nucleosyntheis of heavy elements Some of the previous reactions produce neutrons Those neutrons can be captured by nuclei to form heavier isotopes If these isotopes are unstable, they transmute into the following element by β− disintegration or: etc… These neutroncaptures form the basis of the production of all chemical elements heavier than iron
Nuclear reactions in stars - 10 Abundances of chemical elements Nuclear reactions in stars are responsible for the production of the vast majority of chemical elements heavier than hydrogen and helium (+ Li, Be, B) → starting from carbon The chemical composition of the primitive solar system can be determined by the analysis of some meteorites as well as of the solar spectrum It is representative of what is usually found in the Universe (cosmic abundances) within a common scale factor for carbon and heavier elements This factor is called metallicity
Nuclear reactions in stars - 11 Brown dwarfs If M < 0.08 M and M > 0.013 M = 13 MJup → the core temperature never reaches the value required for hydrogen fusion → gravitational contraction until R ~ RJupTsurf ~ 1000 K • Brief episode of deuteriumfusion (allows to define the limit between brown dwarfs and planets) • gradual cooling → L ~ 10−6L → very hard to detect First detection in 1994: Gliese 229B, double system with a main sequence star
Internal structure of stars Nuclear reactions in the stellar cores (for the Sun, this core extends over 1/4 of the radius (1.6% of the volume) Photosphere Chromosphere Convective zone Core Radiative zone Internal structure of the Sun
Internal structure of stars - 2 Stability of the stellar nuclear reactor Most stars radiate in a very stable way because their energy production is `autoregulated´ If energy production is reduced → central pressure is reduced → the core contracts because of gravity → pressure increases → temperature increases → energy production increases And conversely… → energy production is stabilised at the right level to prevent gravitational collapse
Internal structure of stars - 3 Energy transport 3 mechanisms: • conduction: not efficient in gases → marginal in most stars • radiation: the more transparent matter is, the more efficent is the energy transport by photons; in stars, numerous absorptions – re-emissions • convection: when matter is too opaque, energy accumulates at the bottom of the opaque zone → appearance of convection currents, energy is transported by matter in motion
Internal structure of stars - 4 Internal structure How can we determine the physical state (temperature, pressure,…) in the stellar interiors? A star is a rather simple structure (in 1st approximation) = sphere of gas in equilibrium under its own gravity → solve a system of equations: • hydrostatic equilibrium: pressure ↔ weight of upper layers • mass conservation • energy production • transport (and conservation) of energy • equation of state (ex: perfect gas)
Internal structure of stars - 5 Tests of models Compare predictions with observations (surface conditions) • HR diagrams of clusters (assemblies of stars with same age and same chemical composition) • detection of neutrinos (very low interaction with matter → come directly from the core) • helio and asteroseismology (study of oscillations)