Related papers: Unsupervised detection of decoupled subspaces: many-body scars and beyond

Unsupervised detection of decoupled subspaces: many-body scars and beyond

URL: http://arxiv.org/abs/2201.07151v2
Date: Sun, 5 Jun 2022 21:21:32 GMT
Title: Unsupervised detection of decoupled subspaces: many-body scars and beyond
Authors: Tomasz Szo{\l}dra, Piotr Sierant, Maciej Lewenstein, and Jakub Zakrzewski
Abstract summary: We introduce a quantum-inspired machine learning platform based on a Quantum Variational Autoencoder (QVAE) We demonstrate that the autoencoder trained on a scar state is able to detect the whole family of scar states sharing common features with the input state. The possibility of an automatic detection of subspaces of scar states opens new pathways in studies of models with a weak breakdown of ergodicity.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Highly excited eigenstates of quantum many-body systems are typically featureless thermal states. Some systems, however, possess a small number of special, low-entanglement eigenstates known as quantum scars. We introduce a quantum-inspired machine learning platform based on a Quantum Variational Autoencoder (QVAE) that detects families of scar states in spectra of many-body systems. Unlike a classical autoencoder, QVAE performs a parametrized unitary operation, allowing us to compress a single eigenstate into a smaller number of qubits. We demonstrate that the autoencoder trained on a scar state is able to detect the whole family of scar states sharing common features with the input state. We identify families of quantum many-body scars in the PXP model beyond the $\mathbb{Z}_2$ and $\mathbb{Z}_3$ families and find dynamically decoupled subspaces in the Hilbert space of disordered, interacting spin ladder model. The possibility of an automatic detection of subspaces of scar states opens new pathways in studies of models with a weak breakdown of ergodicity and fragmented Hilbert spaces.

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