Replica symmetry breaking in a quantum-optical vector spin glass

Spin glasses are canonical examples of complex matter. Although much about their structure remains uncertain, they inform the description of a wide array of complex phenomena, ranging from magnetic ordering in metals with impurities to aspects of evolution, protein folding, climate models, combinatorial optimization, and artificial intelligence. Indeed, spin glass theory forms a mathematical basis for neuromorphic computing and brain modeling. Advancing experimental insight into their structure requires repeatable control over microscopic degrees of freedom. Here, we achieve this at the atomic level using a quantum-optical system comprised of ultracold gases of atoms coupled via photons resonating within a confocal cavity. This active quantum gas microscope realizes an unusual type of transverse-field vector spin glass with all-to-all connectivity. Spin configurations are observed in cavity emission and reveal the emergence of replica symmetry breaking and nascent ultrametric structure as signatures of spin-glass order. The driven-dissipative nature of the system manifests as a nonthermal Parisi distribution, in qualitative correspondence with Monte Carlo simulations. The controllability provided by this new spin-glass system, potentially down to the quantum-spin-level, enables the study of spin-glass physics in novel regimes with application to quantum neural network computing.