A flying Schrödinger’s cat in multipartite entangled states

Zhiling Wang(Tsinghua University), Zenghui Bao(Tsinghua University), Yukai Wu(Tsinghua University), Yan Li(Tsinghua University), Weizhou Cai(Tsinghua University), Weiting Wang(Tsinghua University), Yuwei Ma(Tsinghua University), Tianqi Cai(Tsinghua University), Xiyue Han(Tsinghua University), J.-H. Wang(Tsinghua University), Yipu Song(Tsinghua University), Luyan Sun(Tsinghua University), Hongyi Zhang(Tsinghua University), Luming Duan(Tsinghua University)
Science Advances
March 11, 2022
10.1126/sciadv.abn1778
Cited by 62Open Access
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Abstract

Schrödinger's cat originates from the famous thought experiment querying the counterintuitive quantum superposition of macroscopic objects. As a natural extension, several "cats" (quasi-classical objects) can be prepared into coherent quantum superposition states, which is known as multipartite cat states demonstrating quantum entanglement among macroscopically distinct objects. Here, we present a highly scalable approach to deterministically create flying multipartite Schrödinger's cat states by reflecting coherent-state photons from a microwave cavity containing a superconducting qubit. We perform full quantum state tomography on the cat states with up to four photonic modes and confirm the existence of quantum entanglement among them. We also witness the hybrid entanglement between discrete-variable states (the qubit) and continuous-variable states (the flying multipartite cat) through a joint quantum state tomography. Our work provides an enabling step for implementing a series of quantum metrology and quantum information processing protocols based on cat states.

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