Diffusive and Subdiffusive Spin Transport in the Ergodic Phase of a Many-Body Localizable System

Žnidarič, Marko; Scardicchio, Antonello; Varma, Vipin Kerala

doi:10.1103/physrevlett.117.040601

Cited by 296 publications

(407 citation statements)

References 67 publications

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“…Ultimately, these rare regions do thermalize due to being surrounded by thermal regions, which act as a "bath," but their slow dynamics can dominate the long-time or low-frequency dynamics of such a system [58][59][60]. These effects are most dramatic in one dimension, where such inclusions of the MBL phase can bottleneck transport, making the diffusion constant vanish even within the thermal phase, as has been seen in some numerical studies [61,62]. On the other hand, in the MBL phase of a system with quenched randomness there may be rare regions that are less disordered and thus locally thermalizing [41].…”

Section: Introductionmentioning

confidence: 84%

“…The qualitative behavior of transport on the thermal side of the transition at least is mostly settled: both Griffiths estimates [58,59] and large-system numerical approaches [62] indicate that there is a diffusive regime at weak disorder as well as a subdiffusive regime at stronger disorder. However, various questions, concerning the growth of entanglement and the typical behavior of correlation functions in one dimension, are still somewhat poorly understood.…”

Section: Discussionmentioning

confidence: 99%

“…A resolution to this issue was recently provided in the work ofŽnidarič, et al [62], who were able to explore much larger system sizes by an elegant application of matrix product operator techniques. This work considers a finite XXZ spin chain, initially prepared in a fully mixed infinite temperature state, that is connected to simple baths at different magnetic fields at its two ends, such that in this system's nonequilibrium steady state there is (a) a spin density gradient and (b) a spin current along the chain.…”

Section: Numerical Evidencementioning

confidence: 99%

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Rare‐region effects and dynamics near the many‐body localization transition

et al. 2017

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The low-frequency response of systems near the many-body localization phase transition, on either side of the transition, is dominated by contributions from rare regions that are locally "in the other phase", i.e., rare localized regions in a system that is typically thermal, or rare thermal regions in a system that is typically localized. Rare localized regions affect the properties of the thermal phase, especially in one dimension, by acting as bottlenecks for transport and the growth of entanglement, whereas rare thermal regions in the localized phase act as local "baths" and dominate the low-frequency response of the MBL phase. We review recent progress in understanding these rare-region effects, and discuss some of the open questions associated with them: in particular, whether and in what circumstances a single rare thermal region can destabilize the many-body localized phase.

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Section: Introductionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Section: Numerical Evidencementioning

confidence: 99%

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Rare‐region effects and dynamics near the many‐body localization transition

et al. 2017

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“…is the most studied Many-Body-Localization model where numerical results for many observables are available [42][43][44][45][46][47][48][49][50][51][52][53] As explained in the Introduction, besides the usual periodic boundary conditions σ L+1 = σ 1 , it is interesting to consider twisted boundary conditions with some angle φ for the spin operators [21] …”

Section: Many-body-localization Models With Twisted Boundary Condmentioning

confidence: 99%

Many-body-localization transition: sensitivity to twisted boundary conditions

Monthus¹

2017

J. Phys. A: Math. Theor.

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For disordered interacting quantum systems, the sensitivity of the spectrum to twisted boundary conditions depending on an infinitesimal angle φ can be used to analyze the Many-Body-Localization Transition. The sensitivity of the energy levels En(φ) is measured by the level curvature Kn = E ′′ n (0), or more precisely by the Thouless dimensionless curvature kn = Kn/∆n, where ∆n is the level spacing that decays exponentially with the size L of the system. For instance ∆n ∝ 2 −L in the middle of the spectrum of quantum spin chains of L spins, while the Drude weight Dn = LKn studied recently by M. Filippone, P.W. Brouwer, J. Eisert and F. von Oppen [arXiv:1606.07291v1] involves a different rescaling. The sensitivity of the eigenstates |ψn(φ) > is characterized by the susceptibility χn = −F ′′ n (0) of the fidelity Fn = | < ψn(0)|ψn(φ) > |. Both observables are distributed with probability distributions displaying power-law tails2 , where β is the level repulsion index taking the values β GOE = 1 in the ergodic phase and β loc = 0 in the localized phase. The amplitudes A β and B β of these two heavy tails are given by some moments of the off-diagonal matrix element of the local current operator between two nearby energy levels, whose probability distribution has been proposed as a criterion for the Many-Body-Localization transition by M. Serbyn, Z. Papic and D.A. Abanin [Phys. Rev. X 5, 041047 (2015)].

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“…This disorder-induced transition has been under active scrutiny and different probes have been suggested 28 such as subdiffusive power laws in the vicinity of the critical disorder 20 (which may or may not exist 21,[29][30][31][32][33][34][35] ). So far, a full understanding of the MBL transition is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Interaction-induced weakening of localization in few-particle disordered Heisenberg chains

et al. 2017

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We investigate real-space localization in the few-particle regime of the XXZ spin-1/2 chain with a random magnetic field. Our investigation focuses on the time evolution of the spatial variance of non-equilibrium densities, as resulting for a specific class of initial states, namely, pure product states of densely packed particles. Varying the strength of both particle-particle interactions and disorder, we numerically calculate the long-time evolution of the spatial variance σ(t). For the twoparticle case, the saturation of this variance yields an increased but finite localization length, with a parameter scaling different to known results for bosons. We find that this interaction-induced increase is the stronger the more particles are taken into account in the initial condition. We further find that our non-equilibrium dynamics are clearly inconsistent with normal diffusion and instead point to subdiffusive dynamics with σ(t) ∝ t 1/4 .

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Diffusive and Subdiffusive Spin Transport in the Ergodic Phase of a Many-Body Localizable System

Cited by 296 publications

References 67 publications

Rare‐region effects and dynamics near the many‐body localization transition

Rare‐region effects and dynamics near the many‐body localization transition

Many-body-localization transition: sensitivity to twisted boundary conditions

Interaction-induced weakening of localization in few-particle disordered Heisenberg chains

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