Physics 607 Final Exam
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1 Physics 607 Final Exam Please be well-organized, and show all significant steps clearly in all problems You are graded on your work, so please do not ust write down answers with no explanation! o state the obvious: If you are asked for an answer or explanation, it must be clear, precise, and unambiguous Fuzzy answer, argument, or explanation => zero credit Do all your work on the blank sheets provided, writing your name clearly (You may keep this exam) he variables have their usual meanings: E = energy, S = entropy, V = volume, = number of particles, = temperature, P = pressure, µ = chemical potential, B = applied magnetic field, C V = heat capacity at constant volume, C P = heat capacity at constant pressure, F = Helmholtz free energy, G = Gibbs free energy, k = Boltzmann constant, h = Planck constant Also, represents an average e x dx = π x e x dx = 1 π E = k ln Z Z = E e β Z = e β E e x i H x = δ i k 1
2 1 he Gibbs formula for the entropy has the very general form S = k p r ln p r (a) (1) In the canonical ensemble, with the constraint E = E = constant show that maximization of S gives for the probability of a state E p = e β Z where Z is the canonical partition function and β is a Lagrange multiplier (b) (1) In the grand canonical ensemble, with the constraints p E = E = constant and p p r = = constant show that maximization of S gives for the probability of a state with particles p = e β E e Z where Z is the grand partition function and β and are Lagrange multipliers
3 It is possible to create a monolayer of noble gas atoms on a smooth graphite surface Let us therefore consider a -dimensional ideal gas of (spinless nonrelativistic) bosons in an area A (a) (4) Using the fact that the area in momentum space per allowed -dimensional momentum!" p is h / A, obtain the density of states in momentum space ρ ( p) and then the usual density of states ρ ( ε ), where ε is the single-particle energy (b) (4) Let us first treat this system as a classical ideal gas (as is valid at high enough temperatures) Write the classical (canonical) partition function Z as an integral over p x and p y, or over p, or over ε (you may choose), and then evaluate it to get Z as a function of A, h, k,, and the particle mass m (c) (4) Using the partition function, calculate the average energy per particle ε (d) (4) hen obtain ε from the equipartition theorem in the form given on the first page of this exam, and see if the results agree (e) (4) If the system is cooled to low temperatures, it must be treated as a quantum ideal gas he pressure and number of particles are respectively given by ( ) PA k = dε ρ ( ε ε µ ) ln 1 ( e )/k 1 and 0 = dε ρ ( ε ) 0 0 e ( ε µ )/k 1 E Use an integration by parts to relate P to the energy density A when 0 = 0 (f) (4) he integral for 0 can be performed Use your result for this integral to demonstrate whether there is or is not Bose-Einstein condensation in this -dimensional ideal gas of bosons at nonzero temperature (Assume that it remains a liquid down to = 0 ) (g) (4) ow assume that, like the isotopes of helium, this system becomes a crystalline solid under pressure, with vibrations that are described by a -dimensional Debye model he mean-square displacements are given by ω D x = c dω ρ ω 0 ( ) k where c is a constant Obtain the density of states function ρ ( ω ) for -dimensional vibrational modes and determine whether x is finite at nonzero temperatures Assume two modes with the same velocity hese last two parts are examples of the Mermin-Wagner theorem regarding long-range order in dimensions wo of the latest winners of the obel Prize in physics found a way around this theorem involving topological excitations namely, vortices ω 3
4 3 Statistical mechanics spills over into many other areas, including the modeling of how societal collapses occur, with many examples throughout history and in cultures outside history Suppose that we include, under societal collapse, the many cases where a society undergoes a phase transition into an authoritarian repressive regime, or at least one with a dominant political orientation One of the simplest imaginable models is that the probability of a citizen being on the left or right (in political orientation) is proportional to e cδ / I or e cδ / I, where Δ = or Δ = is the net number of citizens who have shifted to that state, c is the strength of the coercive peer pressure, and I is the average intellectual integrity or independence of the citizens, so that = e cδ / I e cδ / I + e cδ / I and = e cδ / I e cδ / I + e cδ / I he polarization is then Δ = ecδ / I e cδ / I e cδ / I + e cδ / I or alternatively Δ = ecδ / I e cδ / I e cδ / I + e cδ / I or, with either choice, Δ = ecδ / I e cδ / I e cδ / I + e cδ / I = tanh c I Δ (a) (9) Sketch a rough plot of tanh c I tanh x sketches) Δ as a function of Δ for c I = 1,1, (his is ust tanh 1 x, ( ), tanh( x) as a function of x Consider small and large values of x to pin down the end points of your (b) (9) For what value of c I is there a phase transition ie, a solution for which the polarization Δ is nonzero? [Common sense says that this is the stable solution he above is, of course, the Weiss mean-field model in a different context, and it may be most appropriate to the formation of fully-aligned political domains analogous to local ferromagnetic domains in the original context] 4
5 4 Here we wish to compare two systems, each of which has a fixed volume V and an energy E which fluctuates Let E be the average energy, with ΔE the usual measure of the size of the fluctuations ( ) = E E ( ) = E E being the variance ie, otice that E and are to be interpreted as the usual thermodynamic variables (internal energy and number of particles), but we use here to avoid confusion But the canonical and the grand canonical can be regarded as equivalent and interchangeable when treated as thermodynamic variables In the first system, the number of particles is fixed, so this system can be described with the canonical ensemble and the canonical partition function Z We will represent the quantities in this case by E C and ( ΔE) C In the second system, the chemical potential is fixed, so this system can be described with the grand canonical ensemble and the grand partition function Z We will represent the quantities in this case by E G and ( ΔE) G In the following, it will be convenient to work with β = 1 k and = µ k as well as and µ You will want to recall the first law of thermodynamics, d E = ds PdV + µd (a) () At a given temperature, which system should have the larger value of ( ΔE)? Why? (Give a clear physical reason) (b) () Obtain an expression for E C ln Z β (c) () Obtain an expression for ΔE ( ) C and C (d) () Obtain an expression for E G lnz β (e) () Obtain an expression for ΔE ( ) G and G (f) () Obtain an expression for G lnz (g) () Obtain an expression for Δ ( ) G G 5
6 (h) () Regarding E as a function of and, obtain the obvious expression for d E d, d, and the partial derivatives of E with respect to and hen obtain = + Finally obtain ( ΔE) G ΔE ( )C = (i) () ow, recalling that the grand canonical potential is defined by Ω = E S µ, obtain dω in terms of d and dµ when V is fixed () () Show that dω = ( S + k )d k d (k) () hen use the result of part () to obtain a relation between ( ) S + k and + (l) () ext, use the first law of thermodynamics ( d E = ds PdV + µd with V fixed) to obtain d( S + k ) d E and d, and from this get ( ) S + k,, and (m) () Combine the results of parts (k) and (l) to obtain a relation between and (n) () Use = and the results of parts (g) and (m) to obtain k = ( Δ ) G (o) () hen use the results of parts (n) and (h) to write ( ΔE) G ( ΔE)C Is this result in accordance with your answer to part (a)? Explain and ( Δ ) G Please have a good summer! 6
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