Time-Dependent Variational Principle for Quantum Lattices

Haegeman, Jutho; Cirac, J. I.; Osborne, Tobias J.; Pižorn, Iztok; Verschelde, Henri; Verstraete, Frank

doi:10.1103/physrevlett.107.070601

Cited by 661 publications

(809 citation statements)

References 23 publications

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“…These are variational state vectors that are described by O (d N D 2 ) variational parameters, where D ∈ N is a refinement parameter and d the dimension of the local Hilbert space. There are several variants of this approach, based on either a Trotter-decomposition [64] or a time-dependent variational principle [25]. Such schemes are subsumed under the term time-dependent density matrix renormalization group method (t-DMRG).…”

Section: Time-dependent Density-matrix Renormalization Group Methodsmentioning

confidence: 99%

Lieb-Robinson Bounds and the Simulation of Time-Evolution of Local Observables in Lattice Systems

Kliesch

Gogolin

Eisert

2014

Many-Electron Approaches in Physics, Chemistry and Mathematics

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This is an introductory text reviewing Lieb-Robinson bounds for open and closed quantum many-body systems. We introduce the Heisenberg picture for time-dependent local Liouvillians and state a Lieb-Robinson bound that gives rise to a maximum speed of propagation of correlations in many body systems of locally interacting spins and fermions. Finally, we discuss a number of important consequences concerning the simulation of time evolution and properties of ground states and stationary states.

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Section: Time-dependent Density-matrix Renormalization Group Methodsmentioning

confidence: 99%

Lieb-Robinson Bounds and the Simulation of Time-Evolution of Local Observables in Lattice Systems

Kliesch

Gogolin

Eisert

2014

Many-Electron Approaches in Physics, Chemistry and Mathematics

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“…18 An essential ingredient of this algorithm is the study of (infinitesimally) small variations of MPS, i.e., the set of MPS tangent vectors. Indeed, it was rigorously proven that the set of MPS can be given the structure of a variational manifold with a well-defined tangent space 36 by eliminating some singular points or regions.…”

Section: A Generic Casementioning

confidence: 99%

“…These tangent states are relevant when studying time evolution or elementary excitations along the lines of analogous MPS algorithms. [18][19][20][21] Before the conclusion in Sec. X, we also discuss how several of the cMPS equations in this manuscript compare to their better known analogues of lattice matrix product states in Sec.…”

Section: Introductionmentioning

confidence: 99%

Calculus of continuous matrix product states

et al. 2013

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We discuss various properties of the variational class of continuous matrix product states, a class of Ansatz states for one-dimensional quantum fields that was recently introduced as the direct continuum limit of the highly successful class of matrix product states. We discuss both attributes of the physical states, e.g., by showing in detail how to compute expectation values, as well as properties intrinsic to the representation itself, such as the gauge freedom. We consider general translation noninvariant systems made of several particle species and derive certain regularity properties that need to be satisfied by the variational parameters. We also devote a section to the translation invariant setting in the thermodynamic limit and show how continuous matrix product states possess an intrinsic ultraviolet cutoff. Finally, we introduce a new set of states, which are tangent to the original set of continuous matrix product states. For the case of matrix product states, this construction has recently proven relevant in the development of new algorithms for studying time evolution and elementary excitations of quantum spin chains. We thus lay the foundation for similar developments for one-dimensional quantum fields.

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“…However TEBD comes into its own for real-time evolution. More recently, a new algorithm, called the time-dependent variational principle (TDVP), 16,17 has also been introduced to study both the realand imaginary-time dynamics for infinite one-dimensional quantum lattices.…”

Section: Introductionmentioning

confidence: 99%

Dynamical windows for real-time evolution with matrix product states

2013

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We propose the use of a dynamical window to investigate the real-time evolution of quantum many-body systems in a one-dimensional lattice. In a recent paper [Phien et al., Phys. Rev. B 86, 245107 (2012)], we introduced infinite boundary conditions in order to investigate real-time evolution of an infinite system under a local perturbation. This was accomplished by restricting the update of the tensors in the matrix product state to a finite region known as a window, with left and right boundaries held at fixed positions. Here we consider instead the use of a dynamical window, where the positions of left and right boundaries are allowed to change in time. In this way, all computational efforts can be devoted to the space-time region of interest, which leads to a remarkable reduction in simulation costs. For illustrative purposes, we consider two applications in the context of the spin-1 antiferromagnetic Heisenberg model in an infinite spin chain: one is an expanding window, with boundaries that are adjusted to capture the expansion in time of a local perturbation of the system; the other is a moving window of fixed size, where the position of the window follows the front of a propagating wave.

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Time-Dependent Variational Principle for Quantum Lattices

Cited by 661 publications

References 23 publications

Lieb-Robinson Bounds and the Simulation of Time-Evolution of Local Observables in Lattice Systems

Lieb-Robinson Bounds and the Simulation of Time-Evolution of Local Observables in Lattice Systems

Calculus of continuous matrix product states

Dynamical windows for real-time evolution with matrix product states

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