Ring Oscillators for Clocking Reversible Superconducting Circuits and Fabrication Process Benchmarking
Vasili K. Semenov, Yuri A. Polyakov, and Sergey K. Tolpygo

TL;DR
This paper demonstrates a Josephson junction-based ring oscillator capable of providing multi-phase bias signals for reversible superconducting circuits, with a focus on fabrication process improvements and energy dissipation analysis.
Contribution
It introduces a novel Josephson junction ring oscillator for multi-phase biasing and benchmarks a fabrication process showing significant reduction in critical current.
Findings
Ring oscillator behavior verified across vortex counts
Energy dissipation per vortex passage estimated at 10kBT
Fabrication process achieves 200-fold reduction in critical current
Abstract
Existing concepts of reversible superconducting circuits as well as demonstrated adiabatic circuits require three-phase bias/clock signals generated by room temperature sources. A while ago, we suggested that a multi-phase bias/clock could be provided by a local Josephson junction-based generator. The generator looks like a long annular Josephson junction, only composed of discreet elements - junctions and inductors, and closed into a ring via a flux pump to inject any required number of vortices into the ring. A steady motion of the vortices forced by a uniformly distributed dc bias current applied to the ring is accompanied by a nearly harmonic ac currents flowing via the Josephson junctions (JJs) connected in series with small inductors. These ac currents serve as multi-phase bias/clock for nSQUID-based circuitry. To verify this concept and compare the dissipated energy with kBTln2…
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