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Quantum Computing with Superconducting Circuits in the Picosecond Regime

Daoquan Zhu, Tuomas Jaako, Qiongyi He, Peter Rabl

2021Physical Review Applied14 citationsDOIOpen Access PDF

Abstract

We discuss the realization of a universal set of ultrafast single- and two-qubit operations with superconducting quantum circuits and investigate the most relevant physical and technical limitations that arise when pushing for faster and faster gates. With the help of numerical optimization techniques, we establish a fundamental bound on the minimal gate time, which is determined independently of the qubit design solely by its nonlinearity. In addition, important practical restrictions arise from the finite qubit transition frequency and the limited bandwidth of the control pulses. We show that, for highly anharmonic flux qubits and commercially available control electronics, elementary single- and two-qubit operations can be implemented in about 100 ps with residual gate errors below ${10}^{\ensuremath{-}4}$. Under the same conditions, we simulate the complete execution of a compressed version of Shor's algorithm for factoring the number 15 in about 1 ns. These results demonstrate that, compared to state-of-the-art implementations with transmon qubits, a hundredfold increase in the speed of gate operations with superconducting circuits is still feasible.

Topics & Concepts

TransmonQubitPhysicsQuantum computerRealization (probability)Electronic circuitAnharmonicityQuantum gateQuantum mechanicsQuantumQuantum circuitQuantum informationComputer scienceUltrashort pulseLogic gateQuantum technologySet (abstract data type)Superconducting quantum computingFactoringSuperconductivityQuantum Fourier transformQuantum error correctionElectronic engineeringPicosecondBandwidth (computing)Topology (electrical circuits)AdderResidualControlled NOT gateQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyLaser-Matter Interactions and Applications
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