Departement Physik, Universit¨ at Basel Prof. C. Bruder (Zimmer 4.2, Tel.: 267-3692, Christoph.Bruder@unibas.ch) H¨ ohere Quantenmechanik, Fru ¨ hjahrsemester 2015 Blatt 9 Abgabe: 21.5.15, 12:00H (Treppenhaus 4. Stock) Tutor: Rakesh Tiwari, Zi. 4.16 Schriftlicher Test: Freitag, 22. Mai 2015, 10.15 - 12 Uhr Hilfsmittel: Ein handbeschriebenes A4 Blatt. (1) Ward identity From [SF (p)]−1 = p/ − m and [SF (p)][SF (p)]−1 = 1, derive (5 Punkte) ∂SF (p) = −SF (p)γ µ SF (p) . ∂pµ Hence, derive the following exact relation between self energy Σ(p) and the vertex function Λµ (p0 , p) ∂Σ(p) − = Λµ (p, p) . ∂pµ (2) Measurement operators (5 Punkte) Consider a two-dimensional Hilbert space with the basis |0i, |1i. Consider a continuous measurement result φ that can √ take values between 0 and 2π. We define the measurement operators Mφ = |φihφ|/ π, where √ |φi = (|0i + exp(iφ)|1i)/ 2 In this case the effects are Eφ = π1 |φihφ|. R 2π (a) Show that 0 dφ Eφ = 1. (b) Is Eφ a projection operator? (c) Show that different effects are not orthogonal in general. (d) If the system is originally in state |φi, what is the probability to measure φ˜ 6= φ? (3) Decoherence and relaxation (5 Punkte) Using the density operator we can describe processes that correspond to a non-unitary time evolution, e.g., the influence of the environment. The density operator ρˆ is mapped on a new density operator ρˆ0 according to X ˆ k ρˆM ˆ† , ρˆ 7−→ ρˆ0 = M (1) k k ˆ k are the measurement operators (or Kraus operators) that characterize the where M influence of the environment. (a) Explain why (1) can be used to model the influence of the environment. (b) Show that ρˆ0 is hermitian and fulfills tr(ˆ ρ0 ) = 1. (c) We consider ρˆ for a single spin 1/2 {|↑i ≡ 10 , |↓i ≡ 01 } under the influence of the Kraus operators √ p p 0 0 0 ˆ1 = ˆ0 = 1 − p 1 ˆ2 = √ M M M p 0 0 0 P ˆ† ˆ where 0 ≤ p ≤ 1 is a probability. Check that k M ˆ0 for k Mk = 1 and calculate ρ a general density matrix ρˆ with matrix elements ρi,j . (d) We now assume that the process (1) describes i.e., during ∆t P a ˆtime evolution, † ˆ the density matrix changes like ρˆ(t + ∆t) = k Mk ρˆ(t)Mk , where p = Γ∆t 1 and Γ > 0 is a rate. What is the time evolution of the matrix elements ρi,j in the continuum limit ∆t → 0 ? Calculate ρˆ(t) for t → ∞. (e) Repeat (c) and (d) for the Kraus operators √ 0 0 1−p 0 ˆ ˆ M1 = √ . M0 = p 0 0 1 Which physical processes are described by the Kraus operators in (c) and (e)? (4) Singlet state Consider two spin 1/2 particles in a singlet state: (5 Punkte) 1 |Ψi = √ (|↑z i1 |↓z i2 − |↓z i1 |↑z i2 ). 2 (a) Show that the singlet state is isotropic, i.e., that its representation is independent of the choice of the quantization axis. For this, express |Ψi in the σ ˆx and in the σ ˆy -eigenbasis. Here, σ ˆx , σ ˆy , σ ˆz are the Pauli matrices, which are related to the spin ˆ ~ ˆ ~ = ~σ . operators via S 2 (b) Consider now a measurement where the spin 1 is measured along an arbitrary direction ~n1 and the spin 2 is measured along a different direction ~n2 . Calculate the probability P↑↑ , for obtaining the result “spin up” for both spins. (Hint: Define an operator that gives the eigenvalue +1 when acting on a spin 1/2 that points along ~n and 0 for acting on a spin that points in the opposite direction). How does the isotropy of the singlet state manifest itself in P↑↑ ?
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