Litcius/Paper detail

Resolving the positions of defects in superconducting quantum bits

Alexander Bilmes, Anthony Megrant, Paul Klimov, Georg Weiss, John M. Martinis, Alexey V. Ustinov, Jürgen Lisenfeld

2020Scientific Reports53 citationsDOIOpen Access PDF

Abstract

Solid-state quantum coherent devices are quickly progressing. Superconducting circuits, for instance, have already been used to demonstrate prototype quantum processors comprising a few tens of quantum bits. This development also revealed that a major part of decoherence and energy loss in such devices originates from a bath of parasitic material defects. However, neither the microscopic structure of defects nor the mechanisms by which they emerge during sample fabrication are understood. Here, we present a technique to obtain information on locations of defects relative to the thin film edge of the qubit circuit. Resonance frequencies of defects are tuned by exposing the qubit sample to electric fields generated by electrodes surrounding the chip. By determining the defect's coupling strength to each electrode and comparing it to a simulation of the field distribution, we obtain the probability at which location and at which interface the defect resides. This method is applicable to already existing samples of various qubit types, without further on-chip design changes. It provides a valuable tool for improving the material quality and nano-fabrication procedures towards more coherent quantum circuits.

Topics & Concepts

QubitQuantum decoherenceQuantumSuperconductivityPhysicsCoupling (piping)Quantum computerField (mathematics)FabricationEnhanced Data Rates for GSM EvolutionOptoelectronicsElectrodeEnergy (signal processing)Condensed matter physicsPhase qubitElectric fieldSample (material)Quality (philosophy)Quantum informationResonance (particle physics)Josephson effectQuantum mechanicsInterface (matter)Flux qubitQuantum technologyMaterials scienceComputer scienceSuperlatticeQuantum and electron transport phenomenaQuantum Computing Algorithms and ArchitectureQuantum-Dot Cellular Automata