Curator's Take
This research demonstrates unprecedented control over superradiance in superconducting qubits, where multiple quantum emitters can synchronize their light emission for dramatically enhanced or suppressed radiative effects. The team's ability to tune both the amplitude and phase of qubit-waveguide couplings while maintaining individual qubit control represents a significant leap beyond previous collective emission experiments that lacked this microscopic precision. Most importantly, they show that strong qubit-qubit interactions can actually protect these collective phenomena from decoherence, opening new pathways for quantum sensing applications where enhanced sensitivity could benefit from engineered superradiant states. This programmable platform bridges fundamental quantum optics with practical quantum technologies, potentially enabling new approaches to quantum-enhanced sensing and information processing.
— Mark Eatherly
Summary
When multiple quantum emitters couple to a common electromagnetic environment, interference in their collective radiative dynamics gives rise to superradiance and subradiance. In regimes where coherent interactions and collective dissipation compete, the microscopic many-body dynamics and quantum correlations among the emitters that underlie superradiance and subradiance are theoretically challenging and remain experimentally elusive, even though collective emission has been observed in many physical systems. Here, we realize a superconducting qubit array coupled to a common microwave waveguide that mediates collective dissipation, with simultaneous access to coherent interactions and microscopic measurements of many-body dynamics. Engineered qubit-waveguide couplings with tunable amplitude and phase enable control of collective interference and the resulting super- and subradiant states. Leveraging site-resolved control and readout, we directly observe the microscopic decay dynamics of multi-qubit states across different excitation manifolds and track the evolution of populations and tunable quantum correlations. We reveal collective decay in regimes beyond the ideal Dicke model, where strong qubit-qubit interactions stabilize superradiance and subradiance against local dephasing and reshape decay pathways through spatially and spectrally structured many-body eigenstates. Our results establish a flexible platform for exploring collective phenomena in many-body quantum optics and driven-dissipative approaches to robust quantum information processing.