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Autores principales: Srdinsek, Miha, Gouraud, Gabriel, Waintal, Xavier
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2604.22718
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author Srdinsek, Miha
Gouraud, Gabriel
Waintal, Xavier
author_facet Srdinsek, Miha
Gouraud, Gabriel
Waintal, Xavier
contents We describe a numerical many-body technique that is based on both tensor networks and quantum Monte Carlo. The variational ansatz is a tensor network that can harvest volume-law entanglement. It is constructed from a tensor train to which one applies a set of non-local operators that force several indices of the tensor train to represent the same physical index, hence its name -- replica tensor train (RTT). From the tensor network toolbox, it inherits the possibility to make linear combinations of these states and apply a certain class of operators. We can therefore find the ground-state of a local Hamiltonian in a purely algebraic way as in standard tensor network algorithms -- i.e. without using gradient descent methods. On the other hand, the volume-law structure forbids calculating physical observables directly. In much the same way as on a quantum computer where one can prepare a state but can only sample it at the end, here we have to use Markov Chain Monte Carlo to compute the observables. We further show that the approach can be extended to build Krylov-subspace ground-state methods within the variational manifold. We illustrate the different algorithms on a two-dimensional spin model with a transverse magnetic field, which can be solved by this approach at low computational cost.
format Preprint
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publishDate 2026
record_format arxiv
spellingShingle Replica Tensor Train
Srdinsek, Miha
Gouraud, Gabriel
Waintal, Xavier
Strongly Correlated Electrons
Disordered Systems and Neural Networks
Quantum Physics
We describe a numerical many-body technique that is based on both tensor networks and quantum Monte Carlo. The variational ansatz is a tensor network that can harvest volume-law entanglement. It is constructed from a tensor train to which one applies a set of non-local operators that force several indices of the tensor train to represent the same physical index, hence its name -- replica tensor train (RTT). From the tensor network toolbox, it inherits the possibility to make linear combinations of these states and apply a certain class of operators. We can therefore find the ground-state of a local Hamiltonian in a purely algebraic way as in standard tensor network algorithms -- i.e. without using gradient descent methods. On the other hand, the volume-law structure forbids calculating physical observables directly. In much the same way as on a quantum computer where one can prepare a state but can only sample it at the end, here we have to use Markov Chain Monte Carlo to compute the observables. We further show that the approach can be extended to build Krylov-subspace ground-state methods within the variational manifold. We illustrate the different algorithms on a two-dimensional spin model with a transverse magnetic field, which can be solved by this approach at low computational cost.
title Replica Tensor Train
topic Strongly Correlated Electrons
Disordered Systems and Neural Networks
Quantum Physics
url https://arxiv.org/abs/2604.22718