Related papers: Introduction to quantum entanglement in many-body systems

Introduction to quantum entanglement in many-body systems

URL: http://arxiv.org/abs/2402.09523v3
Date: Wed, 23 Oct 2024 13:00:18 GMT
Title: Introduction to quantum entanglement in many-body systems
Authors: Anubhav Kumar Srivastava, Guillem Müller-Rigat, Maciej Lewenstein, Grzegorz Rajchel-Mieldzioć,
Abstract summary: The purpose of this chapter is to give a pedagogical introduction to the topic with a special emphasis on the multipartite scenario. We start by providing the necessary mathematical tools and elementary concepts from entanglement theory. Then, we focus on various entanglement structures useful in condensed-matter theory such as tensor-network states or symmetric states useful for quantum-enhanced sensing.
Score: 0.0
License:
Abstract: The quantum mechanics formalism introduced new revolutionary concepts challenging our everyday perceptions. Arguably, quantum entanglement, which explains correlations that cannot be reproduced classically, is the most notable of them. Besides its fundamental aspect, entanglement is also a resource, fueling emergent technologies such as quantum simulators and computers. The purpose of this chapter is to give a pedagogical introduction to the topic with a special emphasis on the multipartite scenario, i.e., entanglement distributed among many degrees of freedom. Due to the combinatorial complexity of this setting, particles can interact and become entangled in a plethora of ways, which we characterize here. We start by providing the necessary mathematical tools and elementary concepts from entanglement theory. A part of this chapter will be devoted to classifying and ordering entangled states. Then, we focus on various entanglement structures useful in condensed-matter theory such as tensor-network states or symmetric states useful for quantum-enhanced sensing. Finally, we discuss state-of-the-art methods to detect and certify such correlations in experiments, with some relevant illustrative examples.

Related papers

A Geometry of entanglement and entropy [0.7373617024876725]
We provide a comprehensive overview of entanglement, highlighting its crucial role in quantum mechanics. We discuss various methods for quantifying and characterizing entanglement through a geometric perspective. An example of entanglement as an indispensable resource for the task of state teleportation is presented at the end.
arXiv Detail & Related papers (2024-02-24T18:26:32Z)
Relaxation of first-class constraints and the quantization of gauge theories: from "matter without matter" to the reappearance of time in quantum gravity [72.27323884094953]
We make a conceptual overview of an approach to the initial-value problem in canonical gauge theories. We stress how the first-class phase-space constraints may be relaxed if we interpret them as fixing the values of new degrees of freedom.
arXiv Detail & Related papers (2024-02-19T19:00:02Z)
Learning, Optimizing, and Simulating Fermions with Quantum Computers [2.810160553339817]
We will explore how the tools of quantum information and computation can assist us on both of these fronts. We primarily do so through the task of partial state learning: tomographic protocols for acquiring a reduced, but sufficient, classical description of a quantum system. At the same time, in the search for such protocols, we also refine our notion of what it means to learn quantum states.
arXiv Detail & Related papers (2023-12-16T09:57:47Z)
Quantum data learning for quantum simulations in high-energy physics [55.41644538483948]
We explore the applicability of quantum-data learning to practical problems in high-energy physics. We make use of ansatz based on quantum convolutional neural networks and numerically show that it is capable of recognizing quantum phases of ground states. The observation of non-trivial learning properties demonstrated in these benchmarks will motivate further exploration of the quantum-data learning architecture in high-energy physics.
arXiv Detail & Related papers (2023-06-29T18:00:01Z)
The Quantum Path Kernel: a Generalized Quantum Neural Tangent Kernel for Deep Quantum Machine Learning [52.77024349608834]
Building a quantum analog of classical deep neural networks represents a fundamental challenge in quantum computing. Key issue is how to address the inherent non-linearity of classical deep learning. We introduce the Quantum Path Kernel, a formulation of quantum machine learning capable of replicating those aspects of deep machine learning.
arXiv Detail & Related papers (2022-12-22T16:06:24Z)
Quantum many-body systems in thermal equilibrium [0.0]
The thermal or equilibrium ensemble is one of the most ubiquitous states of matter. We focus on mathematically rigorous statements, many of them inspired by ideas and tools from quantum information theory.
arXiv Detail & Related papers (2022-04-18T14:46:41Z)
Genuine multipartite entanglement and quantum coherence in an electron-positron system: Relativistic covariance [117.44028458220427]
We analyze the behavior of both genuine multipartite entanglement and quantum coherence under Lorentz boosts. A given combination of these quantum resources is shown to form a Lorentz invariant.
arXiv Detail & Related papers (2021-11-26T17:22:59Z)
An introductory review on resource theories of generalized nonclassical light [0.0]
Quantum resource theory is perhaps the most revolutionary framework that quantum physics has ever experienced. Generalized quantum optical framework strives to bring in several prosperous contemporary ideas.
arXiv Detail & Related papers (2021-03-23T05:10:44Z)
From a quantum theory to a classical one [117.44028458220427]
We present and discuss a formal approach for describing the quantum to classical crossover. The method was originally introduced by L. Yaffe in 1982 for tackling large-$N$ quantum field theories.
arXiv Detail & Related papers (2020-04-01T09:16:38Z)
Bohr meets Rovelli: a dispositionalist account of the quantum limits of knowledge [0.0]
I argue that the no-go theorems reflect on a formal level those practical and experimental settings that are needed to come to know the properties of physical systems. I show that, as a consequence of a relationist and perspectival approach to quantum mechanics, the quantum state of the universe regarded as an isolated system cannot be known in principle.
arXiv Detail & Related papers (2020-01-13T22:45:09Z)
Entanglement Classification via Neural Network Quantum States [58.720142291102135]
In this paper we combine machine-learning tools and the theory of quantum entanglement to perform entanglement classification for multipartite qubit systems in pure states. We use a parameterisation of quantum systems using artificial neural networks in a restricted Boltzmann machine (RBM) architecture, known as Neural Network Quantum States (NNS)
arXiv Detail & Related papers (2019-12-31T07:40:23Z)

This list is automatically generated from the titles and abstracts of the papers in this site.