Exercises for Advanced Solid State Theory Problem set 4, Due date
Transcription
Exercises for Advanced Solid State Theory Problem set 4, Due date
Prof. Dr. Roser Valent´ı M. Altmeyer, S. Backes, K. Riedl Exercises for Advanced Solid State Theory Sommersemester 2015 Problem set 4, Due date: Wednesday, 13.05.15 Exercise 1: Alternative derivation of Curie’s law (5 points) If one writes the free energy FS in the form X X e−βFS = e−βEn = hn|e−βH |ni = Tr e−βH , n (1) n then it is easy to deduce Curie’s law directly at high temperature without going through the algebra of Brillouin functions. Indeed, when H kB T , one can expand e−βH = 1 − βH + (βH)2 /2 − . . . and evaluate the free energy up to second order in the magnetic field, using the fact that (J~ is an operator here) 1 Tr(Jµ Jν ) = δµν TrJ 2 . 3 Then, the high-temperature susceptibility can be extracted using the relation ∂ 2 FS χ= − . ∂B 2 (2) (3) B=0 Calculate the high-temperature susceptibility χ within this approximation for the effective P (i) ~ gµ BJ Hamiltonian H = N z with B = (0, 0, B). B i=1 Exercise 2: Temperature-dependent correction to the Pauli susceptibility (5 points) Show that if T is small compared with the Fermi temperature, the temperature-dependent correction to the Pauli susceptibility χPauli (0) = 2µ2B ρ0 (εF ) is given by " #! 2 0 00 ρ ρ π2 0 − 0 , (4) χPauli (T ) = χPauli (0) 1 − (kB T )2 6 ρ0 ρ0 d2 ρ0 00 0 where ρ0 ≡ ρ0 (ε = εF ), ρ00 ≡ dρ and ρ ≡ . Show that for free electrons 0 dε ε=ε dε2 F ε=εF this reduces to π2 χPauli (T ) = χPauli (0) 1 − 12 1 kB T εF 2 ! . (5) (Hints: The derivation starts from the general formula for the Pauli susceptibility Z ∞ 1 df () 2 , f () = −µ χP auli = −2µB d ρ0 () d e kT + 1 −∞ (6) and then using (i) integration by parts, (ii) the Sommerfeld expansion and (iii) some other formulas from Sec. 5.8 of the ’Solid State Physics I’ script.) 2