Abstract
Quantum matter with exotic topological order has potential applications in quantum computation. However, in present experiments, the manipulations on topological states are still challenging. We here propose an architecture for optical control of topological matter. We consider a topological superconducting qubit array with Su-Schrieffer-Heeger (SSH) Hamiltonian which couples to a microwave cavity. Based on parity properties of the topological qubit array, we propose an optical spectroscopy method to observe topological phase transition, i.e., edge-to-bulk transition. This new method can be achieved by designing cavity-qubit couplings. A main purpose of this work is to understand how topological phase transition affects light-matter interaction. We find that topological bandgap plays an essential role on this issue. In topological phase, the resonant vacuum Rabi splitting of degenerate edge states coupling to the cavity field is protected from those of bulk states by the bandgap. In dispersive regime, the cavity induced coupling between edge states is dominant over couplings between edge and bulk states, due to the topological bandgap. As a result, quantum interference between topological edge states occures and enables single-photon transport through boundaries of the topological qubit array. Our work may pave a way for topological quantum state engineering.
Highlights
Characterization of topological matter is a crucial issue in condensed matter physics [1]
1(d), the topological phase transition can be observed from the reflection of the probe field with special couplings between qubits and the cavity, which can be realized via controllable couplers
We show that the couplings between cavity and edge modes are protected by the topological bandgap, and topological phase (a)
Summary
Wei Nie and Yu-xi Liu1,2,* 1Institute of Microelectronics, Tsinghua University, Beijing 100084, China 2Frontier Science Center for Quantum Information, Beijing 100084, China (Received 5 July 2019; accepted 2 March 2020; published 24 March 2020). We here propose an architecture for optical control of topological matter. We consider a topological superconducting qubit array with a Su-Schrieffer-Heeger (SSH) Hamiltonian which couples to a microwave cavity. Based on parity properties of the topological qubit array, we propose an optical spectroscopy method to observe the topological phase transition, i.e., edge-to-bulk transition. This new method can be achieved by designing cavity-qubit couplings. The resonant vacuum Rabi splitting of degenerate edge states coupling to the cavity field is protected from those of bulk states by the bandgap. Quantum interference between topological edge states occurs and enables single-photon transport through boundaries of the topological qubit array. Our work may pave a way for topological quantum state engineering
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