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Download 763620S Problem Set 2 Autumn 2015 1. Continuous Random Walk
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Transcript
763620S Problem Set 2 Autumn 2015 STATISTICAL PHYSICS 1. Continuous Random Walk Consider a continuous one-dimensional random walk. Let w(si )dsi be the probability that the length of the ith displacement is between si and si + dsi . Assume that the displacements are independent of each other and obey the same distribution w(s). a) Show that the probability of finding the total displacement (after N steps) x= N X si i=1 between x and x + dx is P(x)dx = Z Z ··· Z " w(s1 )w(s2 ) · · · w(sN ) δ x − N X ! # si dx ds1 ds2 · · · dsN , i=1 where δ(x) is the Dirac delta function and the integrations go from −∞ to ∞. b) Show that P(x) = 1 Z∞ dke−ikx QN (k), 2π −∞ where Q(k) = Z ∞ dseiks w(s). −∞ 2. Continuous Random Walk - Discrete Steps Assume that a particle is propagating along a discrete one-dimensional random walk with the probability density w(s) = pδ(s − l) + qδ(s + l), where p (q) is the probability of taking a step of length l to the right (left). Use the results of the previous problem to show that the particle can be found only at locations x = (2n − N )l , n = 0, 1, 2, . . . , N. Show that the probability of finding the particle at those locations is P (2n − N ) = N! pn q N −n . n!(N − n)! (You might need the binomial expansion (x+y)N = 1 R∞ −ikx and the relation δ(x) = 2π .) −∞ dke PN N! n N −n i=1 n!(N −n)! x y 3. H-theorem - Approach to Equilibrium Assume that Pr is the probability of finding the system in the microstate r. The transition probability between any two microstates obeys Wsr = Wrs . a) Write down the ”master equation” governing the time evolution of Pr . b) Show that d hln Pr i ≤ 0, dt where the equality holds when Pr = Ps for all r and s. Interpret this result! 4. Spin System Consider an isolated system of N very weakly interacting localized spin- 12 particles with a magnetic moment µ pointing either parallel or antiparallel to an applied magnetic field B. a) What is the total number of states Ω(E) lying in energy range between E and E + δE, where δE is small compared to E but δE µB? b) Write down the expression for ln Ω(E). Use Stirling’s formula to simplify your result. c) Use Gaussian approximation for Ω(E) when |E| N µB. 5. Approach to Thermal Equilibrium Assume that two systems with different values of β are brought into thermal contact. Show that the system with higher value of β will absorb heat from the other until the two β values are the same.
