Abstract
We propose a superconducting quantum circuit based on a general symmetry principle -- combinatorial gauge symmetry -- designed to emulate topologically-ordered quantum liquids and serve as a foundation for the construction of topological qubits. The proposed circuit exhibits rich features: in the classical limit of large capacitances its ground state consists of two superimposed loop structures; one is a crystal of small loops containing disordered $U(1)$ degrees of freedom, and the other is a gas of loops of all sizes associated to $\mathbb{Z}_2$ topological order. We show that these classical results carry over to the quantum case, where phase fluctuations arise from the presence of finite capacitances, yielding ${\mathbb Z}_2$ quantum topological order. A key feature of the exact gauge symmetry is that amplitudes connecting different ${\mathbb Z}_2$ loop states arise from paths having zero classical energy cost. As a result, these amplitudes are controlled by dimensional confinement rather than tunneling through energy barriers. We argue that this effect may lead to larger energy gaps than previous proposals which are limited by such barriers, potentially making it more likely for a topological phase to be experimentally observable. Finally, we discuss how our superconducting circuit realization of combinatorial gauge symmetry can be implemented in practice.
Highlights
Quantum circuits based on Josephson junctions [1] have increasingly leveraged the techniques of large-scale integrated circuit fabrication in recent years, and this technology has become the basis for the largest quantum information processing systems demonstrated to date [2,3,4]
The goal of this paper is to describe a superconducting quantum circuit based on a symmetry principle—combinatorial gauge symmetry [6]—which can be used to realize topologically ordered states in an engineered quantum system
In this paper we present a proposal for such a system, in the form of a quantum circuit that exhibits exact combinatorial gauge symmetry, including a proposal for how to realize this circuit experimentally
Summary
Quantum circuits based on Josephson junctions [1] have increasingly leveraged the techniques of large-scale integrated circuit fabrication in recent years, and this technology has become the basis for the largest quantum information processing systems demonstrated to date [2,3,4]. The goal of this paper is to describe a superconducting quantum circuit based on a symmetry principle—combinatorial gauge symmetry [6]—which can be used to realize topologically ordered states in an engineered quantum system. In the models considered in those works, a gauge symmetry emerges in the limit where the Josephson energy is dominant and the superconducting phase is the good quantum number. Design a system for which the gauge symmetry is exact at the microscopic level and nonperturbative, holding for any strength of the coupling constants, including regimes where the charging energy dominates Such an exact symmetry should expand the range of parameters for which the topological phase may be stable. In this paper we present a proposal for such a system, in the form of a quantum circuit that exhibits exact combinatorial gauge symmetry, including a proposal for how to realize this circuit experimentally. V we present a detailed discussion of realistic circuit elements needed for an experimental construction
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