Quantum typicality: what is it and what can be done... Jochen Gemmer LMU Muenchen, May, Friday 13th, 2014 University of Osnabrück,
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Quantum typicality: what is it and what can be done... Jochen Gemmer LMU Muenchen, May, Friday 13th, 2014 University of Osnabrück,
Quantum typicality: what is it and what can be done with it? Jochen Gemmer University of Osnabrück, LMU Muenchen, May, Friday 13th, 2014 J.Gemmer quantum typicality Outline Thermal relaxation in closed quantum systems? Typicality in a nutshell Numerical experiment: model, observables and results Typicality in formulas Spin transport in the Heisenberg chain Eigenstate thermalization hypothesis J.Gemmer quantum typicality Thermal relaxation in closed quantum systems? Why it exists: We see it in system we assume to be closed. Why it does not exist: There are issues with the underlying theory: Quantum Mechanics (Non-eq.) Thermodynamics autonomous dynamics of a few macrovariables attractive fixed point, equilibrium often describable by master equations, Fokker-Planck equations, stochastic processes, etc. autonomous dynamics of the wave function (number of parameters: insane) no attractive fixed point (Schroedinger equation) Schroedinger equation is no rate equation Quantum systems that explicitly exhibit relaxation but are not of the “small system + large bath” type appear to be rare in the literature. To cut it short: Why and how do two cups of coffee thermalize each other? J.Gemmer quantum typicality Typicality in a nutshell The naive view on relaxation i.e. 2nd law of thermodynamcis: QM: ρˆ0 = |ψihψ| evolves into 1ˆ ˆ 1 − Hˆ e kT or ρˆeq ≈ δ( H − E) Z Z ρˆeq = problem: invariance of Von Neuman-entropy traditional cure: open quantum systems ⇒ this requires: large, doable, broad band environment (usually oscillators), adequate weak coupling (Van-Hove structure), applicability of projection techniques, specific initial states: factorizing, thermal bath, etc. Typicality: ρˆ0 = |ψihψ| but does not evolve into ˆ hψ|A(t)|ψi ρˆeq = 1 − Hˆ 1ˆ ˆ e kT , ρˆeq = δ( H − E) Z Z evolves into ˆ ≈ Tr{ˆ ρeq A} ˆ |ψi ............ Can this be true? for many (all?) A, J.Gemmer quantum typicality Numerical experiment: model and observables R L spin-model Heisenberg-type Hamiltonian: A ladder with anisotropic, XXZ -type couplings which are strong along the legs and weak along the rungs: X ˆ = Jij (ˆ σxi σ ˆxj + σ ˆyi σ ˆyj + 0.6 σ ˆzi σ ˆzj ), H ij Jij = 1 for solid lines, Jij = κ = 0.2 for dotted lines and Jij = 0 otherwise. Total number of spins: NP= 32. The z-component of total magnetization Sz = i σ ˆzi is conserved We analyze: “magnetization difference” xˆ ! X l X r σ ˆz σ ˆz − xˆ = l ∈L r ∈R eigenvalues of xˆ within the subspace of vanishing total magnetization, Sz = 0: X = −16, −14, ....., +16. J.Gemmer quantum typicality Numerical experiment: results Phys. Rev. E, 89, 042113, (2014) xˆ: z-magnetization difference between legs PX (t): probability to find a certain X H. de Raedt, K. Michielsen (Juelich)) time shifted hˆ x (t)i <x(t)> 12 1 0.8 0.6 <x(0)>=2 <x(0)>=4 <x(0)>=6 <x(0)>=8 <x(0)>=10 <x(0)>=12 8 4 0.4 100 Px(t) 0.2 80 0 15 0 0 60 10 5 40 0 -5 -15 0 |ψX (0)i = e t 100 150 ˆ x P(S ˆ z = 0)|ωi, P (remark: taking this picture took 6h on 65 000 CPU’s. Thanks to: J.Gemmer 12 σ ² (t) data from solving the Schroedinger equation (N = 32) for two pure, partially random initial states: ˆ2 −αH 50 variances of x 20 -10 x t 8 <x(0)>=0 <x(0)>=2 <x(0)>=4 <x(0)>=6 <x(0)>=8 <x(0)>=10 <x(0)>=12 typical variance 4 00 quantum typicality 50 t 100 150 Typicality in formulas Phys. Rev. Lett., 102, 110403 (2009), Phys. Rev. Lett., 86, 1927 (2001) “static typicality” ˆ < A >:= Tr{A}/d : expectation value of the maximally mixed state |ωi uniform random states sampled according to the unitary invariant measure ˆ HA[hω|A|ωi] =< A > ˆ HV[hω|A|ωi] = 1 < A2 > − < A >2 d +1 In a high dimensional Hilbert space almost all possible states feature very similar expectation values for observables with bound spectra. ⇒ It is no surprise to find these “equilibrium” expectation values overwhelmingly often. “dynamical typicality” p |ψi := ρˆd |ωi: “taylored”, non-uniform random states, ˆ ˆ ρ} hψ|A(t)|ψi ≈ Tr{A(t)ˆ ˆ The statisitcal variance of hψ|A(t)|ψi decreases as 1/deff where the latter is the inverse of the largest eigenvalue of ρˆ. ⇒ Very many different pure states exhibit dynamics of expectation values close to those of corresponding mixed states 2 ˆ ¯ 2 ˆ ˆ ˆ If ρˆ is of “exponential form”, e.g., ρˆ ∝ e −β(H−E ) −α(A−A0 ) or ρˆ ∝ e −β H−αA than one may infer dynamics of mixed states from “pure state propagation” J.Gemmer quantum typicality Spin transport in the anisotropic Heisenberg chain 2 (a) L=33 (β=0) norm (a.u.) 0.05 0 (a) ∆=1.0 (β=0) -1 [34,36] [t1,t2] 0 100 tJ -2 10 -1 (b) ∆=1.5 (β=0) 10 -2 10 [20,21] 0.05 [35] 0 1/30 1/20 1/10 1/L 2 -3 10 tJ 20 0.1 0.05 0 J.Gemmer odd fit (β=0) 10 0 even (b) Drude weight (β=0) 0 C(t1,t2) / J C(t) / J 2 L ∆=0.5 ∆=1.0 ∆=1.5 2 L=18 (ED) L=18 L=20 L=22 L=24 L=26 L=28 L=30 (k=0) L=32 (k=0) L=33 (k=0) tDMRG C(t1,t2) / J C(t) / J 2 10 ∆=0.5 ∆=1.0 ∆=1.5 0.1 C(t) / J Linear response ⇒ conductivity from current autocorrelation function ˆ ,A ˆ := Jˆ here: infinite temperature, i.e., ρˆ := J/d ˆ J} ˆ C (t) ∝ Tr{J(t) (PRL., 112, 120601, (2014) ) 0 quantum typicality Bethe Ansatz lower bound ED, fit RK, L=30 RK, L→∞ tDMRG 1 0.5 anisotropy ∆ 1.5 Eigenstate thermalization hypothesis (ETH) ˆ that are close in energy feature ETH: Eigenstates of some Hamiltonian H ˆ that are close to each other. expectation values of some observable A ˆ ˆ En ≈ Em → hn|A|ni ≈ hm|A|mi Jochen’s formulation: “Eigenstates belong to the set of typical states” If ETH applies: - Expecation values from microncanonical ensembles are close to expectation values of individual eigenstates - Initial state independent (ISI) equilibration: X ˆ ρnm Amn e i (En −Em ) t hA(t)i = n,m If the oscillating terms behave like “white noise” for τ large enough ˆ )i = hA(τ X ETH ρnn Ann ≈ Ann n But does ETH apply? Have to check by exact diagonalization, or....... J.Gemmer quantum typicality ETH check for the Heisenberg ladder (Phys. Rev. Lett., 112, 130403, (2014)) ˆ := xˆ2 : width of the magnetization distribution A X 2 ˆ ˆ ¯ := ρnn Ann ≈ hψ|A|ψi ρˆ ∝ e −α(H−U) A n ¯ 2 := Σ +A 2 X ˆ ′ (τ )i] ≈ Re[hψ(τ )|A|ψ ρnn A2nn n (a) L=7 (d) ED 3 2 Ann 6 Ann L=7 1 J|| 0 J 0 0.03 0.02 -1/2 (deff) L=10 0.01 0 ETH applies! L A -4 L=9 L=8 (c) L=10 3 0 6 t1 0 (b) L=9 3 6 180 Σ 0 t J|| 0 3 γ(t) Ann 6 -2 U / J|| 0 A±Σ d=2 2 J.Gemmer L 2L ˆ was a random Σ scales approx like H matrix. quantum typicality Is ISI equilibration always driven by ETH? Back to the two cups of coffee: Temperature differences between macroscopic object always equilibrate, regardless of the objects ⇒ ETH always fulfilled? We ˆ=H ˆL − H ˆ R between all sorts of coupled investigate energy differences A “spin-objects” (a) (b) (a) coupling strength γ=0.36 (c) 0 J L J J L κ γ=0.38 J L R γ=0.41 γ=0.39 -2 10 R R 10 ∆=0.1 ∆=0.6 ∆=0.9 γ=0.29 Σ’ J (b) anisotropy (c) disorder γ=0.41 γ=0.33 0 10 γ=0.32 (d) structure W=0.0 W=0.2 W=2.0 1D 2D γ=0.39 Σ’ κ κ=0.1 κ=0.3 κ=0.6 γ=0.51 γ=0.40 -2 10 1 10 3 10 deff 5 10 1 10 3 10 deff Seems like the ETH is indeed always fulfilled, but what about “integrable” systems ? J.Gemmer quantum typicality 5 10 Is ISI equilibration always driven by ETH? |ωi There appears to be ISI equilibration for large systems Check scaling of Σ The ETH is violated w.r.t. the bare Σ. Define “scaled” ETH parameter Σ/δ: D(t) / D(0) 2 ˆ 2 −β(A−N ˆ L) ) |ψ(0)i ∝ e −αH 0.4 0.2 0 0 100 0.2 2 2 ˆ 1 e −αHˆ }2 ˆ 2 1 e −αAˆ }−Tr{A δ = Tr{A Z Z 0 0 200 400 600 0.1 Σ, (Σ/δ) 2 t 0 ×10 Σ 2 (Σ/δ) 0 0.1 0.2 1/N (erratum : D ⇒ A) J.Gemmer 200 D(0)>0 D(0)<0 (b) |D(0)|=8 2 The scaled ETH parameter appears to vanish in the limit of large systems D(0)>0 D(0)<0 (a) |D(0)|=4 0.4 D(t) / D(0) Consider energy difference dynamics in a clean Heisenberg chain w.r.t. 1:2 partition using initial states like quantum typicality 0.3 The End People who truly did the work: R. Steinigeweg, H. de Raedt, K. Michielsen A. Khodja, D. Schmidtke, C. Gogolin .... Thank you for your attention! The talk itself as well as the mentioned papers may be found on our webpage. J.Gemmer quantum typicality