A tunable coincidence counter based on superconducting nanowire cryotrons
Nai-Tao Liu, Qing-Yuan Zhao, Yang-Hui Huang, Long Wang, Zhen Liu, Jie Deng, Fan Yang, Sai-Ying Ru, Zhen-Guo Li, Yao-Yao Pan, Yu Nie, Shun-Hua Wang, Kang-He Lv, Xue-Cou Tu, Xiao-Qing Jia, La-Bao Zhang, Jian Chen, Lin Kang, Pei-Heng WuSingle-photon coincidence counters are essential components in integrated quantum photonics, enabling efficient logic discrimination and real-time error correction at the chip level. However, monolithic integration at cryogenic temperature remains challenging. Here, we demonstrate a coincidence counter based on superconducting nanowire cryotrons (nTron). The circuit comprises five nTron devices, including delay gates, buffer gates, and an AND gate, achieving a maximum bias margin of 22% at a bit error rate (BER) of 10−5. Operating at 1 MHz, the counter exhibits a static power consumption of 282 nW and a dynamic power consumption of approximately 2 nW at a maximum operation frequency of 17 MHz. The coincidence time window is tunable, with a minimum width below 1 ns, and its position can be adjusted via bias currents. This design offers compatibility with superconducting nanowire single-photon detectors in fabrication and operation, supporting monolithic integration for scalable quantum photonic systems.