Abstract
We formulate a theory of the many-body localization transition based on a novel real space renormalization group (RG) approach. The results of this theory are corroborated and intuitively explained with a phenomenological effective description of the critical point and of the "badly conducting" state found near the critical point on the delocalized side. The theory leads to the following sharp predictions: (i) The delocalized state established near the transition is a Griffiths phase, which exhibits sub-diffusive transport of conserved quantities and sub-ballistic spreading of entanglement. The anomalous diffusion exponent $\alpha < 1/2$ vanishes continuously at the critical point. The system does thermalize in this Griffiths phase. (ii) The many-body localization transition is controlled by a new kind of infinite randomness RG fixed point, where the broadly distributed scaling variable is closely related to the eigenstate entanglement entropy. Dynamically, the entanglement grows as $\sim\log t$ at the critical point, as it also does in the localized phase. (iii) In the vicinity of the critical point the ratio of the entanglement entropy to the thermal entropy, and its variance (and in fact all moments) are scaling functions of $L/\xi$, where $L$ is the length of the system and $\xi$ is the correlation length, which has a power-law divergence at the critical point.
Highlights
In his original paper on localization, Anderson postulated that closed many-body systems undergoing time evolution would not come to thermal equilibrium if subject to sufficiently strong randomness [1]
The recent work led to classification of many-body localization (MBL) as a distinct dynamical phase of matter, characterized by a remarkable set of defining properties: (i) There are locally accessible observables that do not relax to their equilibrium values and can be related to a set of quasilocal integrals of motion [6,7,8,9,10]; (ii) even after arbitrarily long time evolution, retrievable quantum information persists in the system and may be extracted from local degrees of freedom [11,12]; (iii) entanglement entropy grows with time evolution only as a logarithmic function of time [6,13,14,15]
We presented a new renormalization-group framework, which provides a description of the many-body localization transition in one-dimensional systems
Summary
In his original paper on localization, Anderson postulated that closed many-body systems undergoing time evolution would not come to thermal equilibrium if subject to sufficiently strong randomness [1]. The results indicate a universal scaling of the probability distributions of this eigenstate entropy governing the transition from an area law in the insulating phase to the full thermal entropy in the delocalized phase through a critical point where the entropy is broadly distributed with a subthermal volume law. V, we use the RG flow to study the energy transport and propagation of entanglement through the system, showing, in particular, that the dynamical critical exponent z diverges on approaching the critical point from the ergodic side
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