An atomtronic oscillator circuit for quantum gases.

The emerging field of atomtronics aims to build analogue electronic devices using ultracold atomic gases. It has potential applications including inertial and magnetic sensing and quantum simulation. Realising practical atomtronics will require accurate and quantitative circuit models that include basic elements akin to resistors and capacitors. However, there is not yet clear experimental verification of a lumped element description for even the simplest atomtronic circuits. Here we realise a highly-tunable superfluid oscillator circuit in a quantum gas. At low currents we demonstrate that such circuits are accurately described as Helmholtz resonators, a fundamental element of acoustic circuits. At larger currents, the breakdown of the Helmholtz regime is heralded by a turbulent shedding of vortices and density waves. Despite this complex behaviour, the circuit resistance is consistent with simple phase slip models over a wide parameter range. Our realisation of a quantitative model for understanding foundational superfluid circuitry principles will aid the development of atomtronic devices and could also be extended to other technologies, such as those based on superfluid helium and exciton-polariton condensates.