David Logan

The Fock-space landscape of many-body localisation

Journal of Physics: Condensed Matter IOP Publishing 37:7 (2024) 073003

Authors:

Sthitadhi Roy, David E Logan

Abstract:

This article reviews recent progress in understanding the physics of many-body localisation (MBL) in disordered and interacting quantum many-body systems, from the perspective of ergodicity breaking on the associated Fock space. This approach to MBL is underpinned by mapping the dynamics of the many-body system onto that of a fictitious single particle on the high-dimensional, correlated and disordered Fock-space graph; yet, as we elaborate, the problem is fundamentally different from that of conventional Anderson localisation on high-dimensional or hierarchical graphs. We discuss in detail the nature of eigenstate correlations on the Fock space, both static and dynamic, and in the ergodic and many-body localised phases as well as in the vicinity of the MBL transition. The latter in turn sheds light on the nature of the transition, and motivates a scaling theory for it in terms of Fock-space based quantities. We also illustrate how these quantities can be concretely connected to real-space observables. An overview is given of several analytical and numerical techniques which have proven important in developing a comprehensive picture. Finally, we comment on some open questions in the field of MBL where the Fock-space approach is likely to prove insightful.

Scaling of the Fock-space propagator and multifractality across the many-body localization transition

Physical Review B American Physical Society (APS) 106:5 (2022) 054203

Authors:

Jagannath Sutradhar, Soumi Ghosh, Sthitadhi Roy, David E Logan, Subroto Mukerjee, Sumilan Banerjee

Anomalous multifractality in quantum chains with strongly correlated disorder

Physical Review B American Physical Society (APS) 106:2 (2022) l020201

Authors:

Alexander Duthie, Sthitadhi Roy, David E Logan

Fock-space anatomy of eigenstates across the many-body localization transition

Physical Review B American Physical Society 104:17 (2021) 174201

Authors:

Sthitadhi Roy, David E Logan

Abstract:

We explore the Fock-space structure of eigenstates across the many-body localization (MBL) transition in a disordered, interacting quantum spin- 1 2 chain. Eigenstate expectation values of spatially local observables, which distinguish an MBL phase from an ergodic one, can be represented in terms of eigenstate amplitudes on the Fock space. Motivated by this, we introduce and study spatial correlations on the Fock space. From these, a correlation length emerges, which is found to vary discontinuously across the MBL transition, and is intimately connected to the discontinuous jump in the multifractal exponents characterizing the Fock-space wave functions. Exploiting the direct connection between the local observables and Fock-space correlations, we show that the discontinuity in the length scale also implies discontinuous behavior of the local observables across the transition. A scaling theory based on these Fock-space correlations is constructed, which is closely connected to that for the inverse participation ratio. It yields a volume scale in the ergodic phase and a length scale in the MBL phase, whose critical properties suggest a Kosterlitz-Thouless–type scenario for the MBL transition, as is predicted by recent phenomenological theories. Finally, we also show how correlation functions on the Fock space reveal the inhomogeneities in eigenstate amplitudes on the Fock space in the MBL phase.

Localization in quasiperiodic chains: a theory based on convergence of local propagators

Physical Review B American Physical Society 104:6 (2021) 64201

Authors:

Alexander Duthie, Sthitadhi Roy, David Logan

Abstract:

Quasiperiodic systems serve as fertile ground for studying localisation, due to their propensity already in one dimension to exhibit rich phase diagrams with mobility edges. The deterministic and strongly-correlated nature of the quasiperiodic potential nevertheless offers challenges distinct from disordered systems. Motivated by this, we present a theory of localisation in quasiperiodic chains with nearest-neighbour hoppings, based on the convergence of local propagators; exploiting the fact that the imaginary part of the associated self-energy acts as a probabilistic order parameter for localisation transitions and, importantly, admits a continued-fraction representation. Analysing the convergence of these continued fractions, localisation or its absence can be determined, yielding in turn the critical points and mobility edges. Interestingly, we find anomalous scalings of the order parameter with system size at the critical points, consistent with the fractal character of critical eigenstates. The very nature of the theory implies that it goes far beyond the leading-order self-consistent framework introduced by us recently [Phys. Rev. B 103, L060201 (2021)]. Self-consistent theories at high orders are in fact shown to be conceptually connected to the theory based on continued fractions, and in practice converge to the same result. Results are exemplified by analysing the theory for three families of quasiperiodic models covering a range of behaviour.