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Waveguide bandgap engineering with an array of superconducting qubits

Jan David Brehm, Alexander N. Poddubny, Alexander Stehli, Tim Wolz, Hannes Rotzinger, Alexey V. Ustinov

2021npj Quantum Materials57 citationsDOIOpen Access PDF

Abstract

Abstract Waveguide quantum electrodynamics offers a wide range of possibilities to effectively engineer interactions between artificial atoms via a one-dimensional open waveguide. While these interactions have been experimentally studied in the few qubit limit, the collective properties of such systems for larger arrays of qubits in a metamaterial configuration has so far not been addressed. Here, we experimentally study a metamaterial made of eight superconducting transmon qubits with local frequency control coupled to the mode continuum of a waveguide. By consecutively tuning the qubits to a common resonance frequency we observe the formation of super- and subradiant states, as well as the emergence of a polaritonic bandgap. Making use of the qubits quantum nonlinearity, we demonstrate control over the latter by inducing a transparency window in the bandgap region of the ensemble. The circuit of this work extends experiments with one and two qubits toward a full-blown quantum metamaterial, thus paving the way for large-scale applications in superconducting waveguide quantum electrodynamics.

Topics & Concepts

TransmonQubitSuperconducting quantum computingPhysicsMetamaterialQuantumQuantum computerQuantum mechanicsElectromagnetically induced transparencyOptoelectronicsResonance (particle physics)WaveguideSuperconductivityQuantum technologyQuantum informationCondensed matter physicsBand gapQuantum opticsCluster stateStrong Light-Matter InteractionsQuantum Mechanics and Non-Hermitian PhysicsMetamaterials and Metasurfaces Applications
Waveguide bandgap engineering with an array of superconducting qubits | Litcius