Efficient 2D Tensor Network Simulation of Quantum Systems

The phenomenon of many-body localized (MBL) systems has attracted significant interest in recent years, for its intriguing implications from a perspective of both condensed-matter and statistical physics: they are insulators even at non-zero temperature and fail to thermalize, violating expectations from quantum statistical mechanics. What is more, recent seminal experimental developments with ultra-cold atoms in optical lattices constituting analog quantum simulators have pushed many-body localized systems into the realm of physical systems that can be measured with high accuracy. In this work, we introduce experimentally accessible witnesses that directly probe distinct features of MBL, distinguishing it from its Anderson counterpart. We insist on building our toolbox from techniques available in the laboratory, including on-site addressing, super-lattices, and time-of-flight measurements, identifying witnesses based on fluctuations, density–density correlators, densities, and entanglement. We build upon the theory of out of equilibrium quantum systems, in conjunction with tensor network and exact simulations, showing the effectiveness of the tools for realistic models.

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A Geometric View on Quantum Tensor Networks

EPJ Web of Conferences ◽

10.1051/epjconf/202022602022 ◽

2020 ◽

Vol 226 ◽

pp. 02022

Author(s):

Alexander Tsirulev

Keyword(s):

Building Blocks ◽

Quantum Systems ◽

Mixed States ◽

Normal Coordinates ◽

Covariant Derivatives ◽

Tensor Networks ◽

Tensor Network ◽

Network States ◽

Tensor Network States ◽

Arbitrary Quantum

Tensor network states and algorithms play a key role in understanding the structure of complex quantum systems and their entanglement properties. This report is devoted to the problem of the construction of an arbitrary quantum state using the differential geometric scheme of covariant series in Riemann normal coordinates. The building blocks of the scheme are polynomials in the Pauli operators with the coefficients specified by the curvature, torsion, and their covariant derivatives on some base manifold. The problem of measuring the entanglement of multipartite mixed states is shortly discussed.

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Neural-Network Simulation of Strongly Correlated Quantum Systems

10.1007/978-3-030-52715-0 ◽

2020 ◽

Author(s):

Stefanie Czischek

Keyword(s):

Neural Network ◽

Network Simulation ◽

Quantum Systems ◽

Strongly Correlated ◽

Neural Network Simulation ◽

Correlated Quantum Systems

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Simulating boson sampling in lossy architectures

Quantum ◽

10.22331/q-2019-08-05-169 ◽

2019 ◽

Vol 3 ◽

pp. 169 ◽

Cited By ~ 10

Author(s):

Raúl García-Patrón ◽

Jelmer J. Renema ◽

Valery Shchesnovich

Keyword(s):

Optical Fibers ◽

Polynomial Time ◽

Exponential Decay ◽

Thermal Noise ◽

Network Simulation ◽

Single Photons ◽

Linear Optics ◽

Photonic Circuits ◽

Tensor Network ◽

Boson Sampling

Photon losses are among the strongest imperfections affecting multi-photon interference. Despite their importance, little is known about their effect on boson sampling experiments. In this work we show that using classical computers, one can efficiently simulate multi-photon interference in all architectures that suffer from an exponential decay of the transmission with the depth of the circuit, such as integrated photonic circuits or optical fibers. We prove that either the depth of the circuit is large enough that it can be simulated by thermal noise with an algorithm running in polynomial time, or it is shallow enough that a tensor network simulation runs in quasi-polynomial time. This result suggests that in order to implement a quantum advantage experiment with single-photons and linear optics new experimental platforms may be needed.

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