The Sun and the Stars The Sun and the Stars Dr Matt Burleigh The Sun and the Stars The Hertzsprung-Russell Diagram (E. Hertzsprung and H.N. Russell) Plot of surface temperature versus luminosity, or colour (e.g. B-V) versus absolute magnitude M, and various other combinations bright What are the physical mechanisms responsible for the L,T sequence? dim Hot Cool Dr Matt Burleigh The Sun and the Stars The Harvard Classification scheme is an excitation-ionization scheme The physical properties of stellar atmospheres are determined by : i) Temperature, T ii) Pressure, P iii) chemical composition, Dr Matt Burleigh Hydrostatic Equilibrium A star is in hydrostatic equilibrium no net force acting on gas (i.e. gravity balanced by pressure) r=R (r) r P + dP P Centre (r = 0) dr Dr Matt Burleigh The Sun and the Stars In hydrostatic equilibrium no net force acting on gas (i.e. gravity balanced by pressure) Consider a slab of gas area A, thickness r Force due to gravity Fg, is given by GM Fg ma (r ) Ar 2 r This must be balanced by the upward pressure (remember P=F/A), that is GM AP (r ) Ar 2 r rearrange, as r 0, then P GM (r ) 2 r r dP GM (r ) 2 g (r ) dr R where g is the surface gravity, (ie. gravitational acceleration at r=R) If we express the pressure, P in terms of the optical depth, , then d dr æ GM öæ -dt ö dP = -r ç 2 ÷ç ÷ è r øè kr ø dP = g k dt Gas pressure depends on opacity , and surface gravity g Dr Matt Burleigh E.g. Sun’s central pressure What is the pressure at the centre of the Sun? First calculate average density: æ M ö r avg = ç ÷ è 4 / 3p R3 ø M=1.989x1030kg, R=6.96x108m (avg) = 3M /4R3=1410 kgm-3 Then calculate pressure using Hydrostatic Equilibrium: æ GM ö dP = -r (r) ç 2 ÷ è R ø dr Integrate from Pc to P R and from R=R0=0 to R= R, If surface pressure = 0, then Pc~ G M (ave) / R = 2.7x1014 Nm-2 Dr Matt Burleigh The Sun and the Stars We assume that particle densities are high enough that the gas is in thermodynamic equilibrium (i.e. all processes and their inverses occur at the same rate). P nkT The gas obeys the ideal gas law, Where the particle number density n is related to the mass density , and chemical composition (the mean molecular weight), by 1 For pure hydrogen, =1 ionised hydrogen, =1/2 mH n k is Boltzmann’s constant (1.381 10-23JK-1) mH is proton mass (mass of H atom) 1.67x10-27kg (for ionized H there are roughly equal nos. of e- and p+, and me << mp) For stellar interiors, the gas is mostly ionised, and therefore in general 1 3 1 2 X Y Z 1.6 4 2 Where, X is the mass fraction of H Y “” He Z “” metals (all other elements) (mass fraction is the % by mass of one species relative to the total. Ionized H gives two particles per mH) Dr Matt Burleigh The Sun and the Stars What is the temperature at the centre of the Sun? P nkT Combine ideal gas law, And mean molecular weight Re-arranged for n Gives Hence n(r) = P (r) = \T ( r ) = 1 mH n r (r) m (r)mH r ( r ) kT ( r ) m ( r ) mH P(r)m ( r ) mH r (r) k Use Pc and avg estimates, assume ~ ½ (ie pure ionized hydrogen) Then Tc ~ PcmH/(avg) k ~ 1.2x 107K Gas dissociated into ions & electrons but overall electrically neutral… a plasma Dr Matt Burleigh The Sun and the Stars Stellar Thermonuclear Reactions • • • Light elements “burn” to form heavier elements Stellar cores have high enough T and for nuclear fusion Work (after 1938) by Hans Bethe and Fred Hoyle Energy release can be calculated from E=mc2 – e.g. in H fusion 4 x 11H atoms 1 x 42He atom Mass of 4 x 11H atoms = 4 x 1.6729x10-27kg = 6.6916x10-27kg Mass of 1 x 42He atom = 1 x 6.6443x10-27kg E = (4 x 11H atoms1 - 42He atom)c2 = (6.6916x10-27kg - 6.6443x1027kg)c2 = 4.26x10-12J Dr Matt Burleigh Stellar Thermonuclear Reactions • • In the Sun ~10% of its volume is at the T and required for fusion Total energy available is… – Energy per reaction x (total mass available for fusion / mass in each reaction) = Energy per reaction x (0.1 x mass of Sun / mass of 4 x 11H atoms) (where mass of Sun is 2x1030kg) • • • • Hence, Etot = 4.26x10-12 x (2x1029/6.6916x10-27) = 1.27x1044J Lifetime of Sun is then the time taken to fuse all the available mass, which is given by the total energy available Etot divided by the solar luminosity L So, lifetime tsun= Etot/L = 1.27x1044J / 3.9x1026 Js-1 tsun ~ 3.3x1017s ~ 1010yrs Dr Matt Burleigh Stellar Thermonuclear Reactions Proton – proton chain (PPI, T < 2 107K) 3 2 2 1 1 1 H +11 H ®12 H + e+ + n 1.44MeV 2 1 H +11 H ®32 He + g 5.49MeV He +32 He ®24 He +11 H +11 H 12.9MeV is deuterium, PPI occurs 91% of time in Sun, although there are other PP chains H Dr Matt Burleigh b PPI Chain a c 1 1H 11 H 12 H e 2 1H 11 H 32 He 3 3 He 2 2 He 42 He 11 H 11 H Dr Matt Burleigh Stellar Thermonuclear Reactions CNO cycle 12 6 C 11 H 13 7 N 13 7 N 13 6 C 11 N 14 7 N 14 7 N 11 H 15 8 O 15 8 O 15 7 N • • • • • • 13 C e 6 15 N e 7 4 11 H 12 C 6 2 He The Carbon cycle (CNO cycle) also converts H to He but requires a C nucleus as a catalyst Requires temperatures >1.6x107K Occurs in Sun but minor compared to PPI More important fusion process for stellar masses >1.1M sun Since requires a C nucleus, only occurs in Pop I stars Second and fifth steps occur because 13N and 15O are unstable isotopes with half lives of only a few minutes Dr Matt Burleigh CNO Cycle 12 6 C H N 1 1 13 7 13 7 N 13 C e 6 13 6 C 11 H 14 7 N 14 7 N 11 H 15 8 O 15 8 15 7 O 15 N e 7 N H C He 1 1 12 6 4 2 Dr Matt Burleigh Stellar Thermonuclear Reactions At very high temperatures, ~108K, other processes fuse Helium (alpha particles) into heavier elements Triple alpha process: 4 2 He He Be 8 4 Be 24He126C 4 2 8 4 Addition of further alpha particles: 22 24 168O,10 Ne,12 Mg upto Fe • • The triple alpha process is first stage of helium burning in an evolved star that has left the main sequence In most massive stars, then burn C, Ne, O and Mg up to Fe Dr Matt Burleigh