Entanglement concentration of microwave photons based on the Kerr effect in circuit QED

In recent years, superconducting qubits have shown great potential in quantum computation. Hence, microwave photons become very interesting qubits for quantum information processing assisted by superconducting quantum computation. Here, we present a protocol for the entanglement concentration on microwave photons, resorting to the cross-Kerr effect in circuit quantum electrodynamics (QED). Two superconducting transmission line resonators (TLRs) coupled to superconducting molecule with the N-type level structure induce the effective cross-Kerr effect for realizing the quantum nondemolition (QND) measurement on microwave photons. With this device, we present a two-qubit polarization parity QND detector on the photon states of the superconducting TLRs, which can be used to concentrate the nonlocal nonmaximally entangled states of microwave photons assisted by several linear microwave elements efficiently. This protocol has a high efficiency and it may be useful for solid-state quantum information processing assisted by microwave photons.