Litcius/Paper detail

Spin-Boson Quantum Phase Transition in Multilevel Superconducting Qubits

Kuljeet Kaur, Théo Sépulcre, Nicolas Roch, Izak Snyman, Serge Florens, Soumya Bera

2021Physical Review Letters25 citationsDOIOpen Access PDF

Abstract

Superconducting circuits are currently developed as a versatile platform for the exploration of many-body physics, by building on nonlinear elements that are often idealized as two-level qubits. A classic example is given by a charge qubit that is capacitively coupled to a transmission line, which leads to the celebrated spin-boson description of quantum dissipation. We show that the intrinsic multilevel structure of superconducting qubits drastically restricts the validity of the spin-boson paradigm due to phase localization, which spreads the wave function over many charge states. Numerical renormalization group simulations also show that the quantum critical point moves out of the physically accessible range in the multilevel regime. Imposing charge discreteness in a simple variational state accounts for these multilevel effects, which are relevant for a large class of devices.

Topics & Concepts

Superconducting quantum computingPhysicsQubitQuantum mechanicsSuperconductivityCharge (physics)Quantum phase transitionQuantumWave functionRenormalization groupNonlinear systemStatistical physicsPhase transitionQuantum computerPhase (matter)Quantum critical pointFunction (biology)Charge qubitQuantum simulatorSimple (philosophy)Cluster stateDensity matrix renormalization groupCondensed matter physicsPoint (geometry)Theoretical physicsTopology (electrical circuits)Transmission (telecommunications)Quantum informationQuantum dissipationMacroscopic quantum phenomenaQuantum phasesClass (philosophy)Quantum error correctionQuantum circuitState (computer science)Critical point (mathematics)Work (physics)Topological Materials and PhenomenaQuantum many-body systemsPhysics of Superconductivity and Magnetism