Quantum State Transfer via Multi‐Passage Landau–Zener–Stückelberg Interferometry in a Three‐Qubit System

In quantum information processing, it is necessary to transfer quantum state between different systems. Herein, a scheme to transfer quantum state using multi‐passage Landau–Zener–Stückelberg interferometry in three superconducting qubits is proposed. A periodic triangle waveform quickly drives the system across the energy level anticrossing multiple times, inducing multiphoton Rabi oscillations. Using the 0‐photon Rabi oscillations, the dynamical quantum state transfer with probability close to 100% is realized. The fidelity of the state transfer is insensitive to local distortion of the driving waveform. This scheme can be extended to a system where multiple qubits are coupled to a frequency‐tunable qubit, as a quantum medium. It provides a useful tool for scalable quantum computing. In quantum information processing, it is necessary to transfer quantum state between different systems. Herein, a scheme to transfer quantum state using multipassage Landau–Zener–Stückelberg interferometry in three superconducting qubits is proposed. This scheme can be extended to a system where multiple qubits are coupled to a frequency‐tunable qubit and provides a useful tool for two‐qubit quantum gate and superconducting quantum processing.