Deterministic teleportation of a quantum gate between two logical qubits

TL;DR

This paper demonstrates a deterministic quantum gate teleportation between logical qubits in a modular superconducting architecture, advancing fault-tolerant quantum computation and quantum network capabilities.

Contribution

It experimentally realizes a deterministic teleported CNOT gate between logical qubits, a significant step towards robust, error-correctable quantum modules.

Findings

Successfully teleported a CNOT gate deterministically using real-time control.

Implemented the gate between logical qubits encoded in superconducting cavities.

Showed potential for scalable, fault-tolerant quantum computing architectures.

Abstract

A quantum computer has the potential to effciently solve problems that are intractable for classical computers. Constructing a large-scale quantum processor, however, is challenging due to errors and noise inherent in real-world quantum systems. One approach to this challenge is to utilize modularity--a pervasive strategy found throughout nature and engineering--to build complex systems robustly. Such an approach manages complexity and uncertainty by assembling small, specialized components into a larger architecture. These considerations motivate the development of a quantum modular architecture, where separate quantum systems are combined via communication channels into a quantum network. In this architecture, an essential tool for universal quantum computation is the teleportation of an entangling quantum gate, a technique originally proposed in 1999 which, until now, has not been realized deterministically. Here, we experimentally demonstrate a teleported controlled-NOT (CNOT) operation made deterministic by utilizing real-time adaptive control. Additionally, we take a crucial step towards implementing robust, error-correctable modules by enacting the gate between logical qubits, encoding quantum information redundantly in the states of superconducting cavities. Such teleported operations have significant implications for fault-tolerant quantum computation, and when realized within a network can have broad applications in quantum communication, metrology, and simulations. Our results illustrate a compelling approach for implementing multi-qubit operations on logical qubits within an error-protected quantum modular architecture.