Related papers: Band engineering and study of disorder using topology in compact high kinetic inductance cavity arrays

Band engineering and study of disorder using topology in compact high kinetic inductance cavity arrays

URL: http://arxiv.org/abs/2403.18150v1
Date: Tue, 26 Mar 2024 23:19:51 GMT
Title: Band engineering and study of disorder using topology in compact high kinetic inductance cavity arrays
Authors: Vincent Jouanny, Simone Frasca, Vera Jo Weibel, Leo Peyruchat, Marco Scigliuzzo, Fabian Oppliger, Franco De Palma, Davide Sbroggio, Guillaume Beaulieu, Oded Zilberberg, Pasquale Scarlino,
Abstract summary: Superconducting microwave metamaterials offer enormous potential for quantum optics and information science. In the context of circuit quantum electrodynamics, such metamaterials can be implemented as coupled cavity arrays (CCAs) We present a compact CCA architecture leveraging superconducting NbN thin films presenting high kinetic inductance.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Superconducting microwave metamaterials offer enormous potential for quantum optics and information science, enabling the development of advanced quantum technologies for sensing and amplification. In the context of circuit quantum electrodynamics, such metamaterials can be implemented as coupled cavity arrays (CCAs). In the continuous effort to miniaturize quantum devices for increasing scalability, minimizing the footprint of CCAs while preserving low disorder becomes paramount. In this work, we present a compact CCA architecture leveraging superconducting NbN thin films presenting high kinetic inductance, which enables high-impedance CCA ($\sim1.5$ k$\Omega$), while reducing the resonator footprint. We demonstrate its versatility and scalability by engineering one-dimensional CCAs with up to 100 resonators and exhibiting multiple bandgaps. Additionally, we quantitatively investigate disorder in the CCAs using symmetry-protected topological SSH modes, from which we extract a resonator frequency scattering of $0.22^{+0.04}_{-0.03}\%$. Our platform opens up exciting new prospects for analog quantum simulations of many-body physics with ultrastrongly coupled emitters.

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