Phase structure of one-dimensional interacting Floquet systems. II. Symmetry-broken phases
Physical Review B American Physical Society (APS) 93:24 (2016) 245146
Obtaining Highly Excited Eigenstates of Many-Body Localized Hamiltonians by the Density Matrix Renormalization Group Approach.
Physical review letters 116:24 (2016) 247204
Abstract:
The eigenstates of many-body localized (MBL) Hamiltonians exhibit low entanglement. We adapt the highly successful density-matrix renormalization group method, which is usually used to find modestly entangled ground states of local Hamiltonians, to find individual highly excited eigenstates of MBL Hamiltonians. The adaptation builds on the distinctive spatial structure of such eigenstates. We benchmark our method against the well-studied random field Heisenberg model in one dimension. At moderate to large disorder, the method successfully obtains excited eigenstates with high accuracy, thereby enabling a study of MBL systems at much larger system sizes than those accessible to exact-diagonalization methods.Phase Structure of Driven Quantum Systems.
Physical review letters 116:25 (2016) 250401
Abstract:
Clean and interacting periodically driven systems are believed to exhibit a single, trivial "infinite-temperature" Floquet-ergodic phase. In contrast, here we show that their disordered Floquet many-body localized counterparts can exhibit distinct ordered phases delineated by sharp transitions. Some of these are analogs of equilibrium states with broken symmetries and topological order, while others-genuinely new to the Floquet problem-are characterized by order and nontrivial periodic dynamics. We illustrate these ideas in driven spin chains with Ising symmetry.Absolute Stability and Spatiotemporal Long-Range Order in Floquet systems
(2016)
Interaction-stabilized steady states in the driven O(N) model
Physical Review B American Physical Society (APS) 93:17 (2016) 174305