Abstract
Identifying topological properties is a major challenge because, by definition, topological states do not have a local order parameter. While a generic solution to this challenge is not available yet, a broad class of topological states, namely, symmetry-protected topological (SPT) states, can be identified by distinctive degeneracies in their entanglement spectrum. Here, we propose and realize two complementary protocols to probe these degeneracies based on, respectively, symmetry-resolved entanglement entropies and measurement-based computational algorithms. The two protocols link quantum information processing to the classification of SPT phases of matter. They invoke the creation of a cluster state and are implemented on an IBM quantum computer. The experimental findings are compared to noisy simulations, allowing us to study the stability of topological states to perturbations and noise.
Highlights
One of the most important achievements in modern physics is the discovery and classification of topological phases of matter
In this Letter, we address this question for a specific class of topological states, known as symmetry-protected topological (SPT) states
A related property of SPT phases is the possibility to use their ground states as resources for measurement-based quantum computation (MBQC), where the process of computation is driven by local measurements [11,12,13]
Summary
One of the most important achievements in modern physics is the discovery and classification of topological phases of matter. Identification of Symmetry-Protected Topological States on Noisy Quantum Computers The input state is implemented in the protected edge state of the SPT phase and measurements are used to progressively reduce the size of the chain and transfer the information to the opposite edge.
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