Deterministic Quantum State Transfer and Generation of Remote Entanglement using Microwave Photons

TL;DR

This paper demonstrates deterministic quantum state transfer and remote entanglement between superconducting qubits on separate chips using microwave photons, advancing scalable quantum networks and fault-tolerant quantum computing.

Contribution

It introduces a microwave cavity-assisted Raman process for deterministic state transfer and entanglement between remote superconducting qubits, achieving high fidelity and transfer rates.

Findings

State transfer rate of 50 kHz with 98.1% absorption probability

Transfer process fidelity of 80.02%

Remote entanglement fidelity of 78.9%

Abstract

Sharing information coherently between nodes of a quantum network is at the foundation of distributed quantum information processing. In this scheme, the computation is divided into subroutines and performed on several smaller quantum registers connected by classical and quantum channels. A direct quantum channel, which connects nodes deterministically, rather than probabilistically, is advantageous for fault-tolerant quantum computation because it reduces the threshold requirements and can achieve larger entanglement rates. Here, we implement deterministic state transfer and entanglement protocols between two superconducting qubits fabricated on separate chips. Superconducting circuits constitute a universal quantum node capable of sending, receiving, storing, and processing quantum information. Our implementation is based on an all-microwave cavity-assisted Raman process which entangles or transfers the qubit state of a transmon-type artificial atom to a time-symmetric itinerant single photon. We transfer qubit states at a rate of $50 \, \rm{kHz}$ using the emitted photons which are absorbed at the receiving node with a probability of $98.1 \pm 0.1 \%$ achieving a transfer process fidelity of $80.02 \pm 0.07 \%$. We also prepare on demand remote entanglement with a fidelity as high as $78.9 \pm 0.1 \%$. Our results are in excellent agreement with numerical simulations based on a master equation description of the system. This deterministic quantum protocol has the potential to be used as a backbone of surface code quantum error correction across different nodes of a cryogenic network to realize large-scale fault-tolerant quantum computation in the circuit quantum electrodynamic architecture.