ASTM109 Stellar Structure and Evolution Duration: 2.5 hours

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MSc Examination Day 15th May 2014 14:30 17:00 ASTM109 Stellar Structure and Evolution Duration: 2.5 hours YOU ARE NOT PERMITTED TO READ THE CONTENTS OF THIS QUESTION PAPER UNTIL INSTRUCTED TO DO SO BY AN INVIGILATOR. Instructions: Answer ALL question from Section A. Answer ONLY TWO questions from Section B. Section A carries 50 marks; each question in Section B carries 25 marks. If you answer more questions than specified, only the first answers (up to the specified number) will be marked. Cross out any answers that you do not wish to be marked. Calculators ARE permitted in this examination. The unauthorised use of material stored in preprogrammable memory constitutes an examination office. Please state on your answer book the name and type of machine used. Complete all rough workings in the answer book and cross through any work that is not to be assessed. Important note: The academic regulations state that possession of unauthorised material at any time when a student is under examination conditions is an assessment offence and can lead to expulsion from QMUL. Please check now to ensure you do not have any notes, mobile phones or unauthorised electronic devices on your person. If you have any, raise your hand and give them to an invigilator immediately. It is also an offence to have any writing of any kind on your person, including on your body. If you are found to have hidden unauthorised material elsewhere, including toilets and cloakrooms it will be treated as being found in your possession. Unauthorised material found on your mobile phone or other electronic device will be considered the same as being in possession of paper notes. A mobile phone that causes a disruption is also an assessment offence. EXAM PAPERS MUST NOT BE REMOVED FROM THE EXAM ROOM. Examiners: S. Vorontsov D. Burgess c Queen Mary, University of London, 2014

Page 2 ASTM109 (2014) You may assume the following: In all questions: M is the mass, m(r) the mass interior to radius r, R is the radius, L the luminosity and T eff the effective temperature of a star. P, ρ and T denote the pressure, density and temperature respectively. κ is the opacity per unit mass, ϵ the rate of energy production per unit mass and µ denotes the mean molecular weight. c p, c v are the specific heats at constant pressure and volume, γ = c p /c v and R is the gas constant where R = µ(c p c v ). L = 4πR 2 F Rad and F Rad is given by F Rad = 4ac T 3 dt 3 κρ dr. c, G, σ = ac/4 are respectively the velocity of light, the constant of gravity and the Stefan- Boltzmann radiation constant. X, Y, Z are the mass fractions respectively of hydrogen, helium and the heavier elements. The central density ρ c, central temperature T c and central pressure P c of a polytrope of index n are 3M ρ c = a n 4πR, T µgm 3 c = b n RR, P GM 2 c = c n R. 4 The apparent magnitude m app, absolute magnitude M abs and distance in parsecs d are related by m app = M abs + 5logd 5. The following rounded numerical values, all in S.I. Units may be assumed throughout the paper. c = 3 10 8, G = 7 10 11, σ = 6 10 8, M = 2 10 30, R = 7 10 8, L = 4 10 26. You may also assume that 1 year is 3 10 7 seconds.

ASTM109 (2014) Page 3 SECTION A Answer ALL questions in Section A Question A1 A star S has a measured parallax of 0.13 arcsec, and an apparent magnitude of 0.03. Spectroscopic measurements show that the effective temperature of S is two times larger than that of the Sun. What is the visible colour of the star S: is it redder or bluer than the Sun? What is the distance to the star S (in parsecs)? What is its absolute magnitude? The Sun has an absolute magnitude of 4.62. What is the apparent magnitude of a star identical to the Sun, when it is placed at the same distance as S? [8 marks] Question A2 Show that for a fully ionized gas consisting of atomic hydrogen and helium only, the mean molecular weight µ is given by 4 µ = 8 5Y. For a particular homogeneous star, Y = 0.25 while for a second homogeneous star that is more evolved, Y has increased to 0.35. Both stars have the same polytropic index. The central temperature is the same in both stars and may be assumed to be as given in the rubric. If the second star has twice the mass of the first star, calculate the ratio of their radii. [9 marks] Turn over

Page 4 ASTM109 (2014) Question A3 The Lane-Emden equation is ( 1 d ξ 2 dθ ) = θ n, ξ 2 dξ dξ where constant n is the polytropic index. In polytropic stars, the radial profiles of density and pressure are governed by the solution of the Lane-Emden equation θ(ξ) as ρ(r) = ρ c θ n (ξ), P (r) = P c θ n+1 (ξ), where ρ c and P c are central values of density and pressure, and r = αξ with some constant α. Consider a polytropic star with n = 1. Show by direct substitution that the solution to the Lane-Emden equation is θ(ξ) = sin ξ ξ. Deduce the value of ξ at the surface of the star. Find the density (in terms of the central density) and temperature (in terms of the central temperature) at a distance from the centre of 1/3 of the radius. You may assume that the equation of state is that of an ideal gas, and that the mean molecular weight is uniform throughout the star. [8 marks] Question A4 You are given that the gravitational binding energy Ω of a star of polytropic index n is Ω = 3GM 2 (5 n)r, and it is related to the internal energy U by the virial theorem 2U + Ω = 0. Consider a star with a polytropic index n = 3 and no nuclear energy sources. The opacity is assumed to be of the Kramers type so that L M 5.5 R 0.5. Show that such a star will evolve along a line in the HR diagram with a slope of 0.8. Show that t, the time taken by such a star to evolve from a very large radius to some smaller radius R 0, is given by t M 3.5 R0 0.5. [9 marks]

ASTM109 (2014) Page 5 Question A5 Consider a group of homogeneous stars. Each star in the group has the same chemical composition, is homogeneous, and is composed of an ideal gas. Energy generation is by the p-p chain, with ϵ = ϵ 0 ρt 4. All the energy is carried by radiation and the opacity is given by κ = κ 0 ρt 3.5. Show that Also show that M R 13. L M 71/13. Obtain the slope of the line in an H-R diagram (log L versus log T eff ) that these stars lie on. [9 marks] Question A6 In the stellar core where pressure P is dominated by the pressure of the degenerate relativistic electrons, the pressure and density are related by a polytropic law where K is some constant. P = Kρ 4 3, Show that there is only one possible mass for a stellar core where pressure is dominated by the pressure of the degenerate relativistic electrons. Show that when the pressure and the internal energy in the stellar core are dominated by those of the degenerate relativistic electrons, U + Ω = 0, where U is thermal energy, and Ω is gravitational binding energy of the core. Discuss briefly the physical meaning of this result. You may assume without proof that the internal energy density u is u = 3P, and Ω = 3 P dv, where V is the spherical volume occupied by the core. V [7 marks] Turn over

Page 6 ASTM109 (2014) SECTION B Answer TWO questions from Section B Question B1 By considering the forces acting on a volume element, show that for a spherically symmetric star to be in hydrostatic equilibrium: dp dr = Gm(r)ρ r 2. [6 marks] Consider a hypothetical star of mass M and radius R, with uniform density distribution (ρ=const). Find the expressions for m(r) and P (r). [6 marks] Material in the star satisfies the ideal-gas equation of state P = R ρt. Deduce whether the µ star is convectively stable or unstable. [3 marks] d ) Obtain an expression for the gravitational binding energy Ω of the star in terms of M and R. [5 marks] e ) For an ideal gas of classical particles, the internal energy density u is u = 3 P (you can use 2 this relation without a proof). Obtain an expression for the total internal energy U of the star in terms of M and R. Verify that Ω = 2U. [5 marks] Question B2 The interaction of photons with atoms is described in terms of a cross section σ R, which is defined such that nλ ph σ R = 1, where n is the number of atoms per unit volume, and λ ph is the mean free path of a photon. Using geometrical arguments, explain the origin of this definition. [3 marks] The opacity κ is defined as κ = 1 ρλ ph. Show that κ is the total cross section per unit mass.

ASTM109 (2014) Page 7 [3 marks] The optical depth, τ, in a stellar atmosphere is defined as τ = r κρ dr. Starting from the equation for radiative flux, F, given in the rubric, show that in the atmosphere of a star T 4 = 3F (τ + B), ac where B is a constant of integration, which you may assume without proof to be B = 2/3. Using F = σteff 4 as a definition of the effective temperature T eff, show that T 4 = 3 4 T 4 eff ( τ + 2 ). 3 [8 marks] d ) Assume now that this T τ relation is valid everywhere in the radiative atmosphere, including optically thin layers. Explain the possible weaknesses of this assumption. Assume further that the atmosphere is an ideal gas and in hydrostatic equilibrium and that the mass and thickness of the atmosphere are both negligible compared to the mass and radius of the star. Given that P = 0 at τ = 0 and that the opacity is given by κ = κ 0 ρt 5 with some constant κ 0, show that P 2 = P0 2 ln (1 + 3 ) 2 τ, where P 0 is another constant which you do not need to specify. [11 marks] Question B3 The adiabatic exponent γ is defined as γ = ( ) ln P, ln ρ S where subscript S indicates that the partial derivative is taken at constant entropy, i.e. without any heat exchange. Assuming that the equation of state is that of an ideal gas, P = R ρt, show that µ ( ) ln T = γ 1 ln P γ. S [3 marks] Turn over

Page 8 ASTM109 (2014) Derive the Schwarzschild condition for the onset of convection in an ideal gas, namely d ln T d ln P > γ 1 γ. [11 marks] Assume that the temperature- and pressure profiles in the radiative stellar atmosphere are given by the relations T 4 = 3 ( 4 T eff 4 τ + 2 ), 3 P 2 = P0 2 ln (1 + 3 ) 2 τ, where τ is an optical depth, and P 0 is some constant. Assume further that γ = 5/3. Show that the convection sets in at a level where τ = 2 3 [ ( ] 4 exp 1. 5) Question B4 [11 marks] According to Pauli s exclusion principle, at most two electrons can occupy a given energy state, and each particular energy state occupies volume h 3 in the 6-dimensional space of coordinates and momenta, where h is the Planck constant. In a degenerate gas all the electron states are filled up to a threshold momentum p F and none above. Show that the number density of electrons for which momentum p is in the interval (p, p + dp) is n e (p) dp = 8πp2 h 3 when p p F. Show that the total (i.e., integrated over all the possible momenta) electron number density is n e = 8π 3h 3 p3 F. dp [7 marks] Show that when the electrons are moving with speeds small compared to the speed of light, the energy density of the degenerate electrons is u e = 4π 5h 3 m e p 5 F,

ASTM109 (2014) Page 9 and the pressure of the degenerate electrons is P e = 8π 15h 3 m e p 5 F. You may use the general expression E = 1 p 2 for the energy E of a single particle with 2 m momentum p and mass m, and the general relation P = 2 u between pressure P and 3 energy density u in a gas composed of classical particles. [7 marks] Show that in a completely ionized gas, the electron number density, n e, is approximately n e ρ(1 + X) 2m H, where X is mass fraction of hydrogen, and m H is the mass of the hydrogen atom. [4 marks] d ) Show that the analysis of part (b) of this question, which neglects the relativistic effects, is only applicable when ( ) me c 3 ρ m H, h where c is speed of light. [7 marks] End of Paper

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