Abstract
Machine learning, one of today's most rapidly growing interdisciplinary fields, promises an unprecedented perspective for solving intricate quantum many-body problems. Understanding the physical aspects of the representative artificial neural-network states is recently becoming highly desirable in the applications of machine learning techniques to quantum many-body physics. Here, we study the quantum entanglement properties of neural-network states, with a focus on the restricted-Boltzmann-machine (RBM) architecture. We prove that the entanglement of all short-range RBM states satisfies an area law for arbitrary dimensions and bipartition geometry. For long-range RBM states we show by using an exact construction that such states could exhibit volume-law entanglement, implying a notable capability of RBM in representing efficiently quantum states with massive entanglement. We further examine generic RBM states with random weight parameters. We find that their averaged entanglement entropy obeys volume-law scaling and meantime strongly deviates from the Page-entropy of the completely random pure states. We show that their entanglement spectrum has no universal part associated with random matrix theory and bears a Poisson-type level statistics. Using reinforcement learning, we demonstrate that RBM is capable of finding the ground state (with power-law entanglement) of a model Hamiltonian with long-range interaction. In addition, we show, through a concrete example of the one-dimensional symmetry-protected topological cluster states, that the RBM representation may also be used as a tool to analytically compute the entanglement spectrum. Our results uncover the unparalleled power of artificial neural networks in representing quantum many-body states, which paves a novel way to bridge computer science based machine learning techniques to outstanding quantum condensed matter physics problems.
Highlights
Understanding the behavior of quantum many-body systems beyond the standard mean-field paradigm is a central task in condensed-matter physics
We show that their entanglement spectrum has no universal part associated with random matrix theory and bears a Poisson-type level statistics
We randomly sample the weight parameters of the RBM states and compute their entanglement entropy and spectrum. We find that their entanglement entropy exhibits a volume-law scaling, in general. Their entropy is noticeably less than the Page entropy for random pure states, and their entanglement spectrum has no universal part associated with random matrix theory and bears a Poisson-type level statistics
Summary
Understanding the behavior of quantum many-body systems beyond the standard mean-field paradigm is a central (and daunting) task in condensed-matter physics. Notable examples include quantum states with area-law entanglement [4], such as ground states of local gapped Hamiltonians [5] or the eigenstates of many-body localized systems [6], which can efficiently be represented in terms of matrix product states (MPS) [7,8,9] or tensornetwork states, in general [10,11,12] These compact representations of quantum states play a vital role and are indispensable for tackling a variety of many-body problems ranging from the classification of topological phases [13,14] to the construction of the AdS/CFT correspondence [15,16]. The applications of machine-learning techniques to many-body problems would rely vitally on the underlying data structures of the artificial neural networks, whose connections to the entanglement features of the corresponding quantum states are desirable to address. Reveal some crucial aspects of their data structures, which provide a valuable guide for the emerging new field of machine learning and many-body quantum physics
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