Nonadiabatic holonomic quantum computation based on nitrogen-vacancy centers

正Because of quantum superposition,quantum computation can solve many problems,such as factoring large integers[1]and searching unsorted databases[2,3],much faster than classical computation.To realize practical quantum computation and then gain the desired advantages,a universal set of quantum gates with sufficiently high fidelities are needed.However,various inevitable errors reduce the gate fidelities and finally collapse the computation results,which makes the realizations of quantum computation very challenging.To relax     

High-pressure opens new windows for topological materials

正Recently Guo et al.[1]have performed a systematic simulation on the high-pressure phases of the first experimentally available Weyl semimetals TaAs family.Through such a cheap but powerful technique,they theoretically found a new     

Quest towards ultimate performance in superconducting nanowire single photon detectors

正In 2007,superconducting nanowire single photon detectors(SSPD or SNSPD)[1]made an outstanding impact in the field of quantum information technology by demonstrating quantum key distribution(QKD)over a 200-km optical fiber with a 42-dB optical loss using a practical SNSPD system[2].This successful demonstration was realized thanks to its extremely     

Reverse coherent information and its properties

正Channel capacity is a core problem in information theory[1,2].The capacity of a classical channel is essentially characterized by maximum transmission rate of classical information[1].However,in quantum information theory,several capacities can be defined for a quantum channel based on the type of information being sent.Currently,classical capacity[3,4],entanglement-assisted classical capacity[5],quantum capacity[6,7],and private capacity[7]are used to define