Simulating quantum Hall effects on a superconducting quantum processor

The quantum Hall effect, fundamental in modern condensed matter physics, continuously inspires new theories and predicts emergent phases of matter. Analyzing the quantum Hall effect and other intriguing quantum topological phenomena by testing the bulk-edge correspondence remains challenging on quantum simulation platforms. We experimentally demonstrate quantum Hall effects with synthetic dimensions on a programable 30-qubit-ladder superconducting processor. Using a dynamic spectroscopic technique, we directly measure the band structures of the quantum Hall systems along synthetic dimensions with various instances of Aubry-Andr\'{e}-Harper chains. By monitoring the quantum walks of an excitation initialized at the edge qubit, we observe dynamical localization of the topologically protected chiral edge states. With these two signatures of topology, our experiments implement the bulk-edge correspondence in the quantum Hall effect. Moreover, we simulate two different bilayer quantum topological systems on the ladder-type superconducting processor. With the same periodically modulated on-site potentials for two coupled chains, the topologically nontrivial edge states with zero Hall conductivity are observed, while we probe a quantum Hall effect with higher Chern numbers for opposite on-site potentials modulated for two chains. Our work shows the potential of using superconducting qubits for investigating different intriguing topological phases of quantum matter.
Comment: 7+29 pages, 4+29 figures