Generating desired states is a prerequisite in quantum information. Some desired states can be generated by a quantum-scissors device(QSD). We present a detailed analysis of the properties of the generated states, inc...Generating desired states is a prerequisite in quantum information. Some desired states can be generated by a quantum-scissors device(QSD). We present a detailed analysis of the properties of the generated states, including average photon numbers and intensity gains. The theoretical analysis shows that there is a nondeterministic amplification in terms of the average photon number under the condition that the average photon number of the input state is less than 1. In contrast to the input states, the generated states show the nonclassical property described by the negativity of the Wigner function. Furthermore, we generalize the QSD to truncate arbitrary photon number terms of the input states, which may be useful in high-dimensional quantum information processing.展开更多
As a special quantum node in a quantum network,the quantum router plays an important role in storing and transferring quantum information.In this paper,we propose a quantum router scheme based on asymmetric intercavit...As a special quantum node in a quantum network,the quantum router plays an important role in storing and transferring quantum information.In this paper,we propose a quantum router scheme based on asymmetric intercavity couplings and a three-levelΛ-type atomic system.This scheme implements the quantum routing capability very well.It can perfectly transfer quantum information from one quantum channel to another.Compared with the previous quantum routing scheme,our proposed scheme can achieve the transfer rate of single photons from one quantum channel to another quantum channel reaching 100%,the high transfer rate is located in the almost quadrant regions with negative values of the two variablesλa andλb,and their maximum values Tu^b+Td^b=1 emerge in the center pointλa=λb=-1.Therefore,it is possibly feasible to efficiently enhance the routing capability of the single photons between two channels by adjusting the inter-resonator couplings,and the asymmetric intercavity coupling provides a new method for achieving high-fidelity quantum routers.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.11725524,61471356,and 11674089)
文摘Generating desired states is a prerequisite in quantum information. Some desired states can be generated by a quantum-scissors device(QSD). We present a detailed analysis of the properties of the generated states, including average photon numbers and intensity gains. The theoretical analysis shows that there is a nondeterministic amplification in terms of the average photon number under the condition that the average photon number of the input state is less than 1. In contrast to the input states, the generated states show the nonclassical property described by the negativity of the Wigner function. Furthermore, we generalize the QSD to truncate arbitrary photon number terms of the input states, which may be useful in high-dimensional quantum information processing.
基金supported by the Project of Introduction and Cultivation for Young Innovative Talents in Colleges and Universities of Shandong Province。
文摘As a special quantum node in a quantum network,the quantum router plays an important role in storing and transferring quantum information.In this paper,we propose a quantum router scheme based on asymmetric intercavity couplings and a three-levelΛ-type atomic system.This scheme implements the quantum routing capability very well.It can perfectly transfer quantum information from one quantum channel to another.Compared with the previous quantum routing scheme,our proposed scheme can achieve the transfer rate of single photons from one quantum channel to another quantum channel reaching 100%,the high transfer rate is located in the almost quadrant regions with negative values of the two variablesλa andλb,and their maximum values Tu^b+Td^b=1 emerge in the center pointλa=λb=-1.Therefore,it is possibly feasible to efficiently enhance the routing capability of the single photons between two channels by adjusting the inter-resonator couplings,and the asymmetric intercavity coupling provides a new method for achieving high-fidelity quantum routers.
