张蜡宝
电子工程系 博导
 张蜡宝电子工程系 博导 |
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个人简历
张蜡宝,1981年生,金沙威尼斯欢乐娱人城教授、博导,入选国家级青年人才项目、江苏中青年学术带头人、南大青年五四奖章和登峰计划B等。张蜡宝于2010年获金沙威尼斯欢乐娱人城博士学位后留校工作至今,期间多次赴欧洲和日本著名高校从事合作研究;以第一或通信作者在Nature子刊、国家科学评论、Nano Letters等发表SCI论文近五十篇,获授权发明专利16项;多次担任国际学术会议组织委员、分会共主席、主持人和邀请报告等,国家基金、科技奖励和欧盟项目等评审专家等。近年来,主持或参与科技创新2030重大项目、国家重大科研仪器研制项目(部委推荐)、国家重点研发计划、国家自然科学基金重点项目等重大科研任务。 研究方向
超导单光子探测技术、感算一体超导芯片、极端性能超导器件等,及其在激光雷达、激光通信和量子信息等领域的应用。 主要课程
数学物理方法(本科生核心课程),现代电子工程进展(研究生) 招生计划: (1) 博士生:电子科学与技术专业,2024年度名额已满。 (2) 专硕或者学硕:要求获得过电赛省二等奖及以上,2024年度拟招2名左右。 专业要求:电子、光电子、微电子、物理、光学和材料等相关专业背景的优秀同学加入。 欢迎有志于科学研究的优秀学子联系(张老师Lzhang@nju.nju.edu.cn)。 代表成果
2016-至今 发表论文清单: [1] L. Ma, “Van der Waals Self-Epitaxial Growth of Inch-Sized Superconducting Niobium Diselenide Films,” Nano Lett, 2023. (accepted) [2] Y. Guan, “Approaching pixel-level readout of SNSPD array by inductor-shaping pulse,” Applied Physics Letters, 123, 042602, 2023. [3] X. Wang, H. Wang, L. Ma, L. Zhang, Z. Yang, D. Dong, X. Chen, H. Li, Y. Guan, B. Zhang, Q. Chen, L. Shi, H. Li, Z. Qin, X. Tu, L. Zhang, X. Jia, J. Chen, L. Kang, and P. Wu, “Topotactic fabrication of transition metal dichalcogenide superconducting nanocircuits,” Nature Communications, vol. 14, no. 1, pp. 4282, 2023/07/18, 2023. [4] Y. Fei, T. Ji, G. Zhu, L. Zhang, L. Zhang, J. Tan, Q. Chen, Y. Guan, R. Yin, and H. Wang, “Polarizer-free measurement of the full Stokes vector using a fiber-coupled superconducting nanowire single photon detector with a polarization extinction ratio of∼ 2,” Optics Express, vol. 31, no. 2, pp. 2967-2976, 2023. [5] X. Wang, X. Dai, H. Wang, J. Wang, Q. Chen, F. Chen, Q. Yi, R. Tang, L. Gao, L. Ma, C. Wang, X. Wang, G. He, Y. Fei, Y. Guan, B. Zhang, Y. Dai, X. Tu, L. Zhang, L. Zhang, and G. Zou, “All-Water Etching-Free Electron Beam Lithography for On-Chip Nanomaterials,” ACS Nano, Feb 20, 2023. [6] S. Guo, J. Tan, H. Zhang, J. Wang, T. Ji, L. Zhang, X. Hu, J. Chen, J. Xie, K. Zou, Y. Meng, X. Bei, L.-A. Wu, Q. Chen, H. Wang, X. Tu, X. Jia, Q.-Y. Zhao, L. Kang, and P. Wu, “High-timing-precision detection of single X-ray photons by superconducting nanowires,” National Science Review, vol. nwad102, 2023. [7] Y. Dai, K. Jia, G. Zhu, H. Li, Y. Fei, Y. Guo, H. Yuan, H. Wang, X. Jia, and Q. Zhao, “All-fiber device for single-photon detection,” PhotoniX, vol. 4, no. 1, pp. 1-13, 2023. [8] 何广龙, 薛莉, 吴诚, 李慧, 印睿, 董大兴, 王昊, 徐迟, 黄慧鑫, 涂学凑, 康琳, 贾小氢, 赵清源, 陈健, 夏凌昊, 张蜡宝, and 吴培亨, “面向机载平台的小型超导单光子探测系统,” 物理学报, 2023. [9] B. Zhang, Q. Chen, L. B. Zhang, R. Yin, W. L. Yin, Y. Q. Guan, X. W. Hu, C. X. Li, H. Wang, X. C. Tu, Q. Y. Zhao, X. Q. Jia, J. Chen, L. Kang, and P. H. Wu, “An encodable superconducting nanowire trigger,” Applied Physics Letters, vol. 122, no. 15, Apr 10, 2023. [10] Y. Q. Guan, H. C. Li, L. B. Zhang, H. Wang, G. L. He, B. Zhang, Y. Fei, J. Y. Lv, X. Zhang, R. Yin, X. H. Wang, X. C. Tu, Q. Y. Zhao, X. Q. Jia, J. Chen, L. Kang, and P. H. Wu, “SNSPD Array with Single-Channel Readout Based on Compressive Sensing,” Acs Photonics, vol. 9, no. 9, pp. 3102-3109, Sep 12, 2022. [11] G. L. He, H. C. Li, R. Yin, L. B. Zhang, D. X. Dong, J. Y. Lv, Y. Fei, X. H. Wang, Q. Chen, F. Y. Li, H. Li, H. Wang, X. C. Tu, Q. Y. Zhao, X. Q. Jia, J. Chen, L. Kang, and P. H. Wu, “Simultaneous resolution of photon numbers and positions with series-connected superconducting nanowires,” Applied Physics Letters, vol. 120, no. 12, Mar 21, 2022. [12] L. Li, L. He, X. Wu, X. Niu, C. Wan, L. Kang, X. Jia, L. Zhang, Q. Zhao, and X. Tu, “Wideband cryogenic amplifier for a superconducting nanowire single-photon detector,” Frontiers of Information Technology & Electronic Engineering, vol. 22, no. 12, pp. 1666-1676, Dec, 2022. [13] B. A. Zhang, L. B. Zhang, Q. Chen, Y. Q. Guan, G. L. He, Y. Fei, X. H. Wang, J. Y. Lyu, J. R. Tan, H. C. Li, Y. Dai, F. Y. Li, H. Wang, S. L. Yu, X. C. Tu, Q. Y. Zhao, X. Q. Jia, L. Kang, J. Chen, and P. H. Wu, “Photon-assisted Phase Slips in Superconducting Nanowires,” Physical Review Applied, vol. 17, no. 1, pp. 014032, Jan 25, 2022. [14] Y. Q. Guan, H. C. Li, L. Xue, R. Yin, L. B. Zhang, H. Wang, G. H. Zhu, L. Kang, J. Chen, and P. H. Wu, “Lidar with superconducting nanowire single-photon detectors: Recent advances and developments,” Optics and Lasers in Engineering, vol. 156, pp. 107102, Sep, 2022. [15] Y. Fei, T. Ji, L. Zhang, G. Zhu, J. Tan, J. Lv, Q. Chen, G. He, F. Li, X. Wang, H. Li, Y. Guan, R. Yin, H. Wang, X. Jia, Q. Zhao, X. Tu, L. Kang, J. Chen, and P. Wu, “Fast and accurate measurement of the polarization-dependent detection efficiency of superconducting nanowire single photon detectors,” Opt Express, vol. 30, no. 20, pp. 36456-36463, Sep 26, 2022. [16] C. S. Zhang, T. Q. Gao, Y. Y. Cao, Z. W. Fan, H. L. Fu, D. F. Gu, X. D. Han, Y. T. Huang, L. Kang, K. Li, M. Li, R. W. Li, Y. Q. Li, Z. L. Li, Z. B. Li, J. X. Lian, J. C. Liu, Q. Liu, S. Q. Liu, Y. Liu, J. W. Mei, X. Y. Pi, C. G. Shao, J. Sun, Y. J. Tan, Y. H. Tang, L. C. Tu, P. P. Wang, S. J. Wang, P. H. Wu, Q. L. Wu, L. Xiong, Y. H. Xiong, C. Xue, Y. Yan, S. Q. Yang, H. C. Yeh, D. S. Zhai, H. T. Zhang, H. B. Zhang, L. B. Zhang, L. H. Zhang, H. C. Zhao, G. D. Zhou, and J. Luo, “The facilities and performance of TianQin laser ranging station,” Classical and Quantum Gravity, vol. 39, no. 12, pp. 125005, Jun 16, 2022. [17] M. Wu, Y. Lu, H. C. Li, T. Y. Mao, Y. Q. Guan, L. B. Zhang, W. J. He, P. H. Wu, and Q. Chen, “Intensity-guided depth image estimation in long-range lidar,” Optics and Lasers in Engineering, vol. 155, pp. 107054, Aug, 2022. [18] F. Y. Li, Y. Q. Guo, K. J. Liu, L. B. Zhang, Q. Chen, X. H. Wang, B. Zhang, Y. Dai, J. R. Tan, G. L. He, Y. Fei, H. Wang, X. C. Tu, Q. Y. Zhao, X. Q. Jia, L. Kang, J. Chen, and P. H. Wu, “Fast and efficient detection of a single photon with hole-patterned superconductor microstrips,” Applied Physics Letters, vol. 121, no. 12, pp. 122601, Sep 19, 2022. [19] Q. Chen, B. A. Zhang, L. B. Zhang, F. Y. Li, F. F. Jin, H. Han, R. Ge, G. L. He, H. C. Li, J. R. Tan, X. H. Wang, H. Wang, S. L. Yu, X. Q. Jia, Q. Y. Zhao, X. C. Tu, L. Kang, J. Chen, and P. H. Wu, “Suppression of superconductivity dominated by proximity effect in amorphous MoSi nanobelts,” Physical Review B, vol. 105, no. 1, Jan 31, 2022. [20] L. D. Kong, Q. Y. Zhao, H. Wang, Y. H. Huang, S. Chen, H. Hao, J. W. Guo, X. C. Tu, L. B. Zhang, X. Q. Jia, L. Kang, J. Chen, and P. H. Wu, “Probabilistic Energy-to-Amplitude Mapping in a Tapered Superconducting Nanowire Single-Photon Detector,” Nano Letters, vol. 22, no. 4, pp. 1587-1594, Feb 23, 2022. [21] H. Hao, Q. Y. Zhao, L. D. Kong, S. Chen, H. Wang, Y. H. Huang, J. W. Guo, C. Wan, H. Liu, X. C. Tu, L. B. Zhang, X. Q. Jia, J. Chen, L. Kang, C. Li, T. Chen, G. X. Cao, and P. H. Wu, “Improved pulse discrimination for a superconducting series nanowire detector by applying a digital matched filter,” Applied Physics Letters, vol. 119, no. 23, Dec 6, 2021. [22] B. A. Zhang, Q. Chen, Y. Q. Guan, F. F. Jin, H. Wang, L. B. Zhang, T. C. Xue, Q. Y. Zhao, X. Q. Jia, L. Kang, C. Jian, and W. H. Pei, “Research progress of photon response mechanism of superconducting nanowire single photon detector,” Acta Physica Sinica, vol. 70, no. 19, Oct 5, 2021. [23] H. Bao, T. Xu, C. Li, X. Q. Jia, L. Kang, Z. H. Wang, Y. L. Wang, X. C. Tu, L. B. Zhang, Q. Y. Zhao, B. B. Jin, J. Chen, W. W. Xu, and P. H. Wu, “Characterization of Superconducting Nbn, WSi and MoSi Ultra-Thin Films in Magnetic Field,” Ieee Transactions on Applied Superconductivity, vol. 31, no. 5, pp. 1-4, Aug, 2021. [24] T. Xu, S. Chen, H. K. Shi, X. Q. Jia, L. B. Zhang, Q. Y. Zhao, X. C. Tu, L. Kang, J. Chen, and P. H. Wu, “Effect of buffer layer on thermal recovery of superconducting nanowire single-photon detector,” Superconductor Science & Technology, vol. 34, no. 7, Jul, 2021. [25] F. Y. Li, H. Han, Q. Chen, B. Zhang, H. Bao, Y. Dai, R. Ge, S. Y. Guo, G. L. He, Y. Fei, S. C. Yang, X. H. Wang, H. Wang, X. Q. Jia, Q. Y. Zhao, L. B. Zhang, L. Kang, and P. H. Wu, “Saturation efficiency for detecting 1550 nm photons with a 2 x 2 array of Mo0.8Si0.2 nanowires at 2.2 K,” Photonics Research, vol. 9, no. 3, pp. 389-394, Mar, 2021. [26] 高添泉, 张才士, 李明, 李语强, 韩西达, 练军想, 刘胜前, 黎樽彪, 涂良成, and 吴先霖, “中山大学月球激光测距研究与实验,” 中山大学学报 (自然科学版), vol. 60, no. 1-2, pp. 247, 2021. [27] 孔令东, 赵清源, 涂学凑, 张蜡宝, 贾小氢, 康琳, 陈健, and 吴培亨, “超导纳米线延迟线单光子成像器件进展及应用,” 激光与光电子学进展, vol. 58, no. 10, pp. 1011002, 2021. [28] X. D. Zheng, P. Y. Zhang, R. Y. Ge, L. L. Lu, G. L. He, Q. Chen, F. C. Qu, L. B. Zhang, X. L. Cai, Y. Q. Lu, S. N. Zhu, P. H. Wu, and X. S. Ma, “Heterogeneously integrated, superconducting silicon-photonic platform for measurement-device-independent quantum key distribution,” Advanced Photonics, vol. 3, no. 5, pp. 055002-055002, Sep 1, 2021. [29] B. Zhang, Y. Q. Guan, L. H. Xia, D. X. Dong, Q. Chen, C. Xu, C. Wu, H. X. Huang, L. B. Zhang, L. Kang, J. Chen, and P. H. Wu, “An all-day lidar for detecting soft targets over 100 km based on superconducting nanowire single-photon detectors,” Superconductor Science & Technology, vol. 34, no. 3, pp. 034005, Mar, 2021. [30] Z. Y. Liu, B. C. Luo, L. B. Zhang, B. Y. Hou, and D. Y. Wang, “Vortex dynamics in amorphous MoSi superconducting thin films,” Superconductor Science & Technology, vol. 34, no. 12, pp. 125014, Dec, 2021. [31] H. Wang, J. Chen, Y. Lin, X. Wang, J. Li, Y. Li, L. Gao, L. Zhang, D. Chao, X. Xiao, and J. M. Lee, “Electronic Modulation of Non-van der Waals 2D Electrocatalysts for Efficient Energy Conversion,” Adv Mater, vol. 33, no. 26, pp. e2008422, Jul, 2021. [32] Q. Chen, R. Ge, L. Zhang, F. Li, B. Zhang, F. Jin, H. Han, Y. Dai, G. He, Y. Fei, X. Wang, H. Wang, X. Jia, Q. Zhao, X. Tu, L. Kang, J. Chen, and P. Wu, “Mid-infrared single photon detector with superconductor Mo(0.8)Si(0.2) nanowire,” Sci Bull (Beijing), vol. 66, no. 10, pp. 965-968, May 30, 2021. [33] L. D. Kong, Q. Y. Zhao, H. Wang, J. W. Guo, H. Y. B. Lu, H. Hao, S. Y. Guo, X. C. Tu, L. B. Zhang, X. Q. Jia, L. Kang, X. L. Wu, J. Chen, and P. H. Wu, “Single-Detector Spectrometer Using a Superconducting Nanowire,” Nano Letters, vol. 21, no. 22, pp. 9625-9632, Nov 24, 2021. [34] H. Wang, J. M. Chen, Y. P. Lin, X. H. Wang, J. M. Li, Y. Li, L. J. Gao, L. B. Zhang, D. L. Chao, X. Xiao, and O. M. Lee, “Electronic Modulation of Non-van der Waals 2D Electrocatalysts for Efficient Energy Conversion,” Advanced Materials, vol. 33, no. 26, Jul, 2021. [35] X. Tao, H. Hao, X. Li, S. Chen, L. B. Wang, X. C. Tu, X. Q. Jia, L. B. Zhang, Q. Y. Zhao, L. Kang, and P. H. Wu, “Characterize the Speed of a Photon-Number-Resolving Superconducting Nanowire Detector,” Ieee Photonics Journal, vol. 12, no. 4, pp. 1-8, Aug, 2020. [36] X. Li, J. R. Tan, K. M. Zheng, L. B. Zhang, L. J. Zhang, W. J. He, P. W. Huang, H. C. Li, B. Zhang, Q. Chen, R. Ge, S. Y. Guo, T. Huang, X. Q. Jia, Q. Y. Zha, X. C. Tu, L. Kang, J. Chen, and P. H. Wu, “Enhanced photon communication through Bayesian estimation with an SNSPD array,” Photonics Research, vol. 8, no. 5, pp. 637-641, May 1, 2020. [37] B. Zhang, Q. Chen, L. B. Zhang, R. Ge, J. R. Tan, X. Li, X. Q. Jia, L. Kang, and P. H. Wu, “Approaching linear photon-number resolution with superconductor nanowire array,” Applied Physics B-Lasers and Optics, vol. 126, no. 4, pp. 1-8, Mar 7, 2020. [38] J. Liao, Y. Yin, J. Yu, R. Zhang, T. Wu, H. Li, Q. Sun, L. Zhang, and W. Zheng, “Depth-resolved NIR-II fluorescence mesoscope,” Biomed Opt Express, vol. 11, no. 5, pp. 2366-2372, May 1, 2020. [39] J. Yu, R. Zhang, Y. Gao, Z. Sheng, M. Gu, Q. Sun, J. Liao, T. Wu, Z. Lin, P. Wu, L. Kang, H. Li, L. Zhang, and W. Zheng, “Intravital confocal fluorescence lifetime imaging microscopy in the second near-infrared window,” Opt Lett, vol. 45, no. 12, pp. 3305-3308, Jun 15, 2020. [40] K. Sugiura, Z. Yin, R. Okamoto, L. Zhang, L. Kang, J. Chen, P. Wu, S. T. Chu, B. E. Little, and S. Takeuchi, “Broadband generation of photon-pairs from a CMOS compatible device,” Applied Physics Letters, vol. 116, no. 22, pp. 224001, Jun 1, 2020. [41] K. Zheng, Q. Y. Zhao, H. Y. Lu, L. D. Kong, S. Chen, H. Hao, H. Wang, D. F. Pan, X. C. Tu, L. B. Zhang, X. Q. Jia, J. Chen, L. Kang, and P. H. Wu, “A Superconducting Binary Encoder with Multigate Nanowire Cryotrons,” Nano Lett, vol. 20, no. 5, pp. 3553-3559, May 13, 2020. [42] S. Guo, Q. Chen, D. Pan, Y. Wu, X. Tu, G. He, H. Han, F. Li, X. Jia, Q. Zhao, H. Zhang, X. Bei, J. Xie, L. Zhang, J. Chen, L. Kang, and P. Wu, “Fabrication of superconducting niobium nitride nanowire with high aspect ratio for X-ray photon detection,” Sci Rep, vol. 10, no. 1, pp. 9057, Jun 3, 2020. [43] P. Xiao, X. C. Tu, C. T. Jiang, Z. J. Li, S. Y. Zhou, D. F. Pan, Q. Y. Zhao, X. Q. Jia, L. B. Zhang, L. Kang, J. Chen, and P. H. Wu, “Planar double-slot antenna integrated into a Nb5N6 microbolometer THz detector,” Optics Letters, vol. 45, no. 10, pp. 2894-2897, May 15, 2020. [44] 李祝莲, 翟东升, 张海涛, 皮晓宇, 伏红林, 李荣旺, 李鹏飞, 张蜡宝, and 李语强, “基于超导探测器的白天卫星激光测距试验与研究,” 红外与激光工程, vol. 49, no. 8, pp. 20190536-1-20190536-6, 2020. [45] Q. Chen, B. Zhang, L. B. Zhang, R. Ge, R. Y. Xu, Y. Wu, X. C. Tu, X. Q. Jia, D. F. Pan, L. Kang, J. Chen, and P. H. Wu, “Sixteen-Pixel NbN Nanowire Single Photon Detector Coupled With 300-mu m Fiber,” Ieee Photonics Journal, vol. 12, no. 1, Feb, 2020. [46] K. Zheng, Q. Y. Zhao, L. D. Kong, S. Chen, H. Y. Lu, X. C. Tu, L. B. Zhang, X. Q. Jia, J. Chen, L. Kang, and P. H. Wu, “Characterize the switching performance of a superconducting nanowire cryotron for reading superconducting nanowire single photon detectors,” Sci Rep, vol. 9, no. 1, pp. 16345, Nov 8, 2019. [47] R. Y. Xu, X. Tao, Q. Chen, X. Li, G. H. Zhu, L. Kang, L. B. Zhang, X. Q. Jia, X. C. Tu, Q. Y. Zhao, B. B. Jin, W. W. Xu, J. Chen, and P. H. Wu, “Experimental Demonstration of Superconducting Series Nanowire Photon-Number-Resolving Detector at 660 nm Wavelength,” Ieee Photonics Journal, vol. 11, no. 1, pp. 1-8, Feb, 2019. [48] J. Jin, F. F. Fu, X. Q. Jia, L. Kang, Z. H. Wang, X. C. Tu, L. B. Zhang, B. B. Jin, J. Chen, W. W. Xu, and P. H. Wu, “Preparation and Characterization of Ultrathin WSi Films for Superconducting Nanowire Single-Photon Detectors,” Ieee Transactions on Applied Superconductivity, vol. 29, no. 5, pp. 1-4, Aug, 2019. [49] P. Zhong, J. Xie, R. Bagheri, Q. Yi, Q. Chen, J. Tan, L. He, F. Zhang, L. Zhang, and G. Zou, “An aqueous solution method towards Sb(2)S(3) thin films for photoanodes,” Chem Commun (Camb), vol. 55, no. 96, pp. 14530-14533, Nov 28, 2019. [50] K. Sugiura, R. Okamoto, L. Zhang, L. Kang, J. Chen, P. Wu, S. T. Chu, B. E. Little, and S. Takeuchi, “An on-chip photon-pair source with negligible two photon absorption,” Applied Physics Express, vol. 12, no. 2, pp. 022006, 2019. [51] H. Zhang, L. Xiao, B. Luo, J. Guo, L. Zhang, and J. Xie, “The potential and challenges of time-resolved single-photon detection based on current-carrying superconducting nanowires,” Journal of Physics D: Applied Physics, vol. 53, no. 1, pp. 013001, 2019. [52] X. Tao, S. Chen, Y. J. Chen, L. B. Wang, X. Li, X. C. Tu, X. Q. Jia, Q. Y. Zhao, L. B. Zhang, L. Kang, and P. H. Wu, “A high speed and high efficiency superconducting photon number resolving detector,” Superconductor Science & Technology, vol. 32, no. 6, pp. 064002, Jun, 2019. [53] X. Y. Zhang, L. Jia, J. Zhu, X. C. Yan, L. B. Zhang, L. Fang, and P. H. Wu, “Comparison of laser ranging system based on SNSPD and SPAD detectors,” Journal of Infrared and Millimeter Waves, vol. 37, no. 3, pp. 378-384, Jun, 2018. [54] R. Li, S. Xie, L. Zhang, L. Li, D. Kong, Q. Wang, R. Xin, X. Sheng, L. Yin, and C. Yu, “Soft and transient magnesium plasmonics for environmentaland biomedical sensing,” Nano Research, pp. 1-11, 2018. [55] R. Xu, Y. Li, F. Zheng, G. Zhu, L. Kang, L. Zhang, X. Jia, X. Tu, Q. Zhao, B. Jin, W. Xu, J. Chen, and P. Wu, “Demonstration of a superconducting nanowire single photon detector with an ultrahigh polarization extinction ratio over 400,” Opt Express, vol. 26, no. 4, pp. 3947-3955, Feb 19, 2018. [56] X. Tu, C. Jiang, P. Xiao, L. 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