A superconducting silicon chip is used as an unreliable relay host for secure quantum communication. By exploiting the exceptionally low dead time function of the single-photon waveguide integrated in the waveguide (the pink wire has a hairpin in the center), the ringing state measurements are encoded in the time compartment. The optimal (shown in blue and gray waveforms between 4-photon curves, represented as pink balls) is realized. In contrast, these improve the secure locking fee of quantum communication. Credit Score: MaLab, Nanjing College
The researchers tackled a longstanding problem in quantum optics: the measurement of the optimal Bell state of time-encoded qubits, to underpin the importance of secure quantum communication.
Integrated quantum photonics (IQP) is a promising platform for realizing scalable and streamlined quantum data processing. Up to this point, a lot of testing with IQP deals with improved sound, high quality and complexity of tests for conventional platforms based mainly on digital optical components. bulk and fiber optics. A more rigorous question is: “Are there tests that can be done with IQP that would be unthinkable with conventional expertise?”
This question was answered affirmatively by a staff member headed by Xiao-Track Ma and Labo Zhang from Nanjing College, and Xinlun Cai from Solar Yat-sen College, China. As reported in Superior Photonics, employees realize quantum communication using a chip primarily based on silicon photonics with a superconducting nanowire single-photon detector (SNSPD). The excellent performance of this chip allows them to understand the optimal time Bell state measurement and greatly improves the overhead that is important in quantum communication.
The single photon detector is a key component for quantum key distribution (QKD) and is extremely attractive for integrating photonics chips to understand scalable and rational quantum networks. By exploiting the special high-speed function of the optical waveguide integrated SNSPD, the non-existent single-photon detection time is reduced by more than an order of magnitude compared with the normal emission frequency SNSPD. In turn, this allows the workers to solve one of the many longstanding challenges in quantum optics: the optimal Bell-state measurement of qubits encoded in the time bin.
This advancement is necessary not only for the field of quantum optics from a fundamental perspective, but also for quantum communications from an application perspective. Employees use the unique benefits of the superconducting, heterogeneously integrated silicon photonic platform to understand the instrumentation-independent quantum key delivery server (MDI-QKD). This successfully eliminates all possible detector side-channel attacks and thus greatly enhances the security of quantum cryptography. Combined with the time multiplexing method, this tactic obtains a large improvement in the MDI-QKD locking fee.
(a) Test setup diagram. A superconducting silicon photonic chip that performs optimal Bell state measurements is used as a host for MDI-QKD, allowing Alice and Bob to securely trade keys with detector side-channel attacks. (b) Harmful and constructive interference in coincidence is calculated when Alice and Bob send identical states (blue dot) or completely different states (pink dot). (c) Safety lock fee under completely different losses. Credit score: Zheng et al., Doi 10.1117 / 1.AP.3.5.055002
By exploiting some of the great benefits of this heterogeneous built-in system, employees get an excessively secure lockout at 125 MHz, which corresponds to the MDI-QKD test results. The most modern with a GHz clock fee. Xiaodong Zheng, a doctoral student in Ma’s group and the first author of Superior Photonic Paper.
“This work shows that integrated quantum photonic chips are not only the path to miniaturization, but also significantly improve system efficiency compared to conventional platforms. Combined with the integrated QKD generators, a fully chip-based, scalable, and high primary rate urban quantum community will be realized in the near future,” Ma said.
Reference: “Heterogeneously integrated, superconducting silicon photonic platform for instrumentation-independent quantum key delivery” by Xiaodong Zheng, Peiyu Zhang, Renyou Ge, Liangliang Lu, Guanglong He, Qi Chen, Fangchao Qu, LaBao Zhang, Xinlun Cai , Yanqing Lu, Shining N. Zhu, Peiheng Wu, Xiaosong Ma, October 30, 2021, Superior Photonics.
DOI: 10.1117 / 1.AP.3.5.055002
