郑耀辉

郑耀辉,男,1979年生,教授,博导国家杰出青年基金获得者

德国马普学会爱因斯坦研究所高级访问学者,三晋学者特聘教授,主要致力于激光技术、连续变量非经典光场制备与应用、量子精密测量、量子传感、光量子器件等方面的理论与实验研究以及高品质量子光源等高技术成果转化。

近年来,作为项目负责人先后承担国家杰出青年基金,国家重点研发项目课题、国家重大科研仪器研制项目、国家863计划项目、国家自然科学基金、装备预研航天科工联合基金和省部级科研项目等等,作为骨干也参与国家973计划、国家自然科学基金仪器专项、面上项目等多项。先后在Phys. Rev. Lett, Laser & Photonics Rev, Photon. Res., Opt. Lett, Opt. Express等国内外重要学术刊物上发表论文100余篇,授权美国专利一项,中国发明专利数50余项,在中国光学学会学术会议等重要会议受邀作报告20余次。

荣誉情况:

2008年荣获“全国专利运用与产业化先进工作者”荣誉称号;

2011年入选山西大学首批“青年英才计划”;

2014年入选山西省优秀青年学术带头人;

2018年度山西省“三晋英才”支持计划拔尖人才。

科研奖励:

“利用非线性光学效应提升全固态单频连续波激光器整体性能的关键技术” 荣获2021年山西省技术发明一等奖;

“不同波长瓦级全固态单频激光器2012年度山西省技术发明一等奖

成果鉴定:

高功率全固态连续单频绿光激光器,鉴定结论:“整体指标国际先进,部分指标国际领先”。

科研项目

1、 国家杰出青年基金,超低噪声激光光源,62225504,2023年1月-2027年12月、400万、在研、主持;

2、国家重点研发计划课题,星载激光功率放大器噪声抑制与评估,2020YFC2200402,2021年1月-2025年12月、797万、在研、主持;

3、国家重大科研仪器研制项目,亚音频段非经典光源研制,62027821,2021年1月-2025年12月、764.6万、在研、主持;

4、 ***创新特区省市推荐项目,量子**项目,2020.12-2022.11,200万,在研,主持;

5、国家自然科学基金应急重点项目,用于引力波探测的音频段压缩真空态的实验制备,11654002,2017.01-2021.12,400万,已结题,主持;

6、 山西省重点研发计划,量子信息关键器件攻关研究,2019-2021,100万,主持,参与;

7、装备预研航天科工联合基金项目,量子光场高效耦合技术,6141B07090108,2017.12-2019.11,100万,已结题,主持;

8、国家863计划、2011AA030203、单频激光器关键技术、2011年1月-2012年12月、888万元、已结题,主持;

9、 国家自然科学基金面上项目、61575114、与锂原子跃迁线相匹配的压缩真空态的实验制备、2016年1月-2019年12月、75.6万元、已结题,主持;

10、山西省优秀青年学术带头人、2014年7月、10万元;

11、国家自然科学基金仪器专项、61227015、连续变量量子纠缠态样机的研制,2013年1月-2016年12月,已结题,2/参与;

12、国家自然科学基金青年基金、61008001、1.3 μm波段连续变量量子纠缠态的制备及其在光纤中传输特性的研究、2011年1月-2013年12月、22万元、已结题,主持;

13、国家973计划、2010CB923101、具有实用价值的纠缠态光源研制、2010年1月-2014年8月、640万元、已结题、3/参与;

14、国家自然科学基金仪器专项、60527003、瓦级全固态连续单频激光器、2006年1月-2008年12月、80万元、已结题、参与;

15、 山西省自然科学基金、2011021003-2、1.3 μm波段连续变量量子纠缠态的制备及其在光纤中传输特性的研究、2011年6月—2014年6月、8万元、已结题、主持;

16、 山西省专利实施资助、111001、《单频可调谐激光》中试、2011年3月—2012年3月、8万元、已结题、主持。

代表性论文:

1. Y. Wu , Q. Wang, L. Tian, X. Zhang, J. Wang, S. Shi, Y. Wang, Y. Zheng, “Multi-channel multiplexing quantum teleportation based on the entangled sideband modes. Photon. Res. 10(1909-1914)2022

2. Sun, X., Wang, Y., Tian, Y., Wang, Q., Tian, L., Zheng, Y., & Peng, K. Deterministic and Universal Quantum Squeezing Gate with a Teleportation Like Protocol. Laser & Photonics Reviews, 2100329 (2021).

3. Shaoping Shi, Long Tian, Yajun Wang, Yaohui Zheng, Changde Xie, and Kunchi Peng, Demonstration of Channel Multiplexing Quantum Communication Exploiting Entangled Sideband Modes, Physical Review Letters, 125 070502 (2020).

4. Jiao, N.; Li, R.; Wang, Y.; Zhang, W.; Zhang, C.; Tian, L.; Zheng, Y. Laser Phase Noise Suppression and Quadratures Noise Intercoupling in a Mode Cleaner. Optics & Laser Technology 2022, 154, 108303.

5. Yuhang Tian, Xiaocong Sun, Yajun Wang*, Qinghui Li, Long Tian, and Yaohui Zheng*.Cavity enhanced parametric homodyne detection of a squeezed quantum comb. Opt. Lett. 47, 533-536 (2022)

6. Li, W., Peng, Y., Yu, X., Chen, L., & Zheng, Y. Phase-sensitive manipulation of squeezed vacuum via a dual-recycled Michelson interferometer. Optics Express, 29(21), 34826-34834(2021).

7. Wang, Q., Li, W., Wu, Y., Yao, W., Li, F., Tian, L., ... & Zheng, Y. Demonstration of 1 3 continuous-variable quantum telecloning. Physical Review A, 104(3), 032419(2021).

8. Tian, L., Shi, S., Li, Y., Wu, Y., Li, W., Wang, Y., ... & Zheng, Y. Entangled sideband control scheme via frequency-comb-type seed beam. Optics Letters, 46(16), 3989-3992(2021).

9. Zhang, W., Jiao, N., Li, R., Tian, L., Wang, Y., & Zheng, Y. Precise control of squeezing angle to generate 11 dB entangled state. Optics Express, 29(15), 24315-24325(2021).

10. Wang, Q., Tian, Y., Li, W., Tian, L., Wang, Y., & Zheng, Y. High-fidelity quantum teleportation toward cubic phase gates beyond the no-cloning limit. Physical Review A, 103(6), 062421(2021).

11. Zhang, W., Li, R., Wang, Y., Wang, X., Tian, L., & Zheng, Y. Security analysis of continuous variable quantum key distribution based on entangled states with biased correlations. Optics Express, 29(14), 22623-22635(2021).

12. Yao, W., Wang, Q., Tian, L., Li, R., Shi, S., Wang, J., ... & Zheng, Y. Realizing high efficiency 532 nm laser by optimizing the mode-and impedance-matching. Laser Physics Letters, 18(1), 015001(2020).

13. Y. Wang, W. Zhang, R. Li, L. Tian, and Y. Zheng, "Generation of −10.7 dB unbiased entangled states of light," Applied Physics Letters 118, 134001 (2021).

14. Q. Wang, Y. Wang, X. Sun, Y. Tian, W. Li, L. Tian, X. Yu, J. Zhang, and Y. Zheng, "Controllable continuous variable quantum state distributor," Opt Lett 46, 1844-1847 (2021).

15. Y. Wang, Y. Tian, X. Sun, L. Tian, and Y. Zheng, "Noise transfer of pump field noise with analysis frequency in a broadband parametric downconversion process," Chinese Optics Letters 19, 052703 (2021).

16. Shaoping Shi, Yajun Wang, Long Tian, Jinrong Wang, Xiaocong Sun, and Yaohui Zheng. Observation of a comb of squeezed states with strong squeezing factor by a bichromatic local oscillator.Opt. Lett. 45(8), 2419-2422 (2020).

17. Jinrong Wang, Qingwei Wang, Long Tian, Jing Su, and Yaohui Zheng.A low-noise, high-SNR balanced homodyne detector for the bright squeezed state measurement in 1–100 kHz range, Chinese Physics B 29, 034205 (2020).

18. 王俊萍, 张文慧, 李瑞鑫, 田龙, 王雅君, 郑耀辉, 宽频带压缩态光场光学参量腔的设计物理学报,69(23): 234204(2020).

19. 田宇航, 王俊萍, 杨文海, 田龙, 王雅君, 郑耀辉. 集成量子压缩光源中MgOLiNbO3晶体倍频系统研究. 中国激光, 47(11): 1108001(2020).

20. 田龙, 王庆伟, 姚文秀, 李庆回, 王雅君, 郑耀辉 高效外腔倍频产生 426 nm 激光的实验研究,物理学报 69(4), 044201(2020).

21. 王雅君, 高丽, 张晓莉, 郑耀辉. 用于精密测量的低噪声激光器研究进展(特邀) 红外与激光工程, 49(12): 20201073-20201073 (2020).

22. Jin-Rong Wang, Hong-Yu Zhang, Zi-Lin Zhao, and Yao-Hui Zheng. Realization of ultralow power phase locking by optimizing Q factor of resonant photodetector. Chin. Phys. B Vol. 29, No. 12 (2020) 124207

23. L. Tian, S. Shi, Y. Tian, Y. Wang, Y. Zheng, and K. Peng, "Resource reduction for simultaneous generation of two types of continuous variable nonclassical states," Frontiers of Physics 16, 21502 (2020).

24. W. Yao, Q. Wang, L. Tian, R. Li, S. Shi, J. Wang, Y. Wang, and Y. Zheng, "Realizing high efficiency 532 nm laser by optimizing the mode- and impedance-matching," Laser Physics Letters 18, 015001 (2020).

25. Xiaocong Sun, Yajun Wang, Long Tian, Shaoping Shi, Yaohui Zheng, Kunchi Peng, Dependence of the squeezing andanti-squeezing factors of bright squeezed light on the seed beam power and pumpbeam noise, OpticsLetters, 44 (7) 1789 (2019)

26. Qingwei Wang, Long Tian, Wenxiu Yao, Yajun Wang, Yaohui Zheng, Realizing a high-efficiency 426nm laserwith PPKTP by reducing mode-mismatch caused by the thermal effect, Optics Express, 27(20)28534 (2019)

27. Wenhui Zhang, Jinrong Wang, Yaohui Zheng, Yajun Wang, Kunchi Peng, Optimization of the squeezing factor bytemperature-dependent phase shift compensation in a doubly resonant opticalparametric oscillator, AppliedPhysics Letters, 115 171103 (2019)

28. Zhixiu Li, Yuhang Tian, Yajun Wang, Weiguang Ma, Yaohui Zheng, Residual amplitude modulation and itsmitigation in wedged electro-optic modulator ZhixiuLi, Yuhang Tian, Yajun Wang, Weiguang Ma, Yaohui Zheng, Optics Express, 27(5)7064 (2019)

29. Xiaocong Sun, Yajun Wang, Long Tian, Shaoping Shi, Yaohui Zheng, Kunchi Peng, Detection of 13.8 dB squeezed vacuumstates by optimizing the interference efficiency and gain of balanced homodynedetection, Xiaocong Sun, Yajun Wang, Long Tian, Yaohui Zheng, Kunchi Peng, ChineseOptics Letters, 17(7) 072701 (2019)

30. Jinrong Wang, Wenhui Zhang, Long Tian, Yajun Wang, Rongcao Yang, Jing Su, Yaohui Zheng, BalancedHomodyne Detector With Independent Phase Control and Noise Detection Branches JinrongWang, Wenhui Zhang, Long Tian, Yajun Wang, Rongcao Yang, Jing Su, Yaohui Zheng IEEEAccess 7:57054 (2019)

31. Long Tian, Xiaocong Sun, Qingwei Wang, Jinrong Wang, Wenxiu Yao, Junping Wang, Yaohui Zheng, Kunchi Peng, Utilizing Sequential Control Scheme to Stabilize Squeezed Vacuum States, Applied Science, 2019, 9, 1861

32. Zhixiu Li, Xiaocong Sun, Yajun Wang, Yaohui Zheng, Kunchi Peng, Investigation of residual amplitude modulation in squeezed state generation system, Optics Express, 2018, 26, 18957-18968

33. Long Tian, Zhongxiao Xu, Shujing Li, Yaohui Zheng, Yafei Wen, Hai Wang, Enhanced-generation of atom-photon entanglement by using FPGA-based feedback protocol, Optics Express, 2018, 26, 20160-20173

34. Shaoping Shi, Yajun Wang, Wenhai Yang, Yaohui Zheng, Kunchi Peng, Detection and perfect fitting of 13.2 dB squeezed vacuum states by considering green-light-induced infrared absorption, Optics Letters, 2018, 43, 5411-5414

35. Chaoyong Chen, Shaoping Shi, Yaohui Zheng, Low-noise, transformer-coupled resonant photodetector for squeezed state generation, Review of Scientific Instruments, 88, 103101 (2017)

36. Wenhai Yang, Xiaoli Jin, Xudong Yu, Yaohui Zheng, Kunchi Peng, Dependence of measured audio-band squeezing level on local oscillator intensity noise, Optics Express, 2017, 25, 24262-24271

37. Yajun Wang, Wenhai Yang, Zhixiu Li, Yaohui Zheng, Determination of blue-lightinduced infrared absorption based on mode-matching efficiency in an optical parametric oscillator , Scientific Reports, 2017, 7, 41405

38. Yajun Wang, Zhixiu Li, Yaohui Zheng, Jing Su, Determination of the Thermal Lens of a PPKTP Crystal Based on Thermally Induced Mode-Mismatching, IEEE JOURNAL OF QUANTUM ELECTRONIC, 2017, 53, 7000307

39. Wenhai Yang, Shaoping Shi, Yajun Wang, Weiguang Ma, Yaohui Zheng, Kunchi Peng, Detection of stably bright squeezed light with the quantum noise reduction of 12.6 dB by mutually compensating the phase fluctuations, Optics Letters, 2017, 42, 4553-4556

40. Zhixiu Li, Weiguang Ma, Wenhai Yang, Yajun Wang, Yaohui Zheng, Kunchi Peng, Reduction of zero baseline drift of the Pound–Drever–Hall error signal with a wedged electro-optical crystal for squeezed state generation, Optics Letters, 2016, 41, 3331-3334

41. Chaoyong Chen, Zhixiu Li, Xiaoli Jin, Yaohui Zheng, Resonant photodetector for cavity- and phase-locking of squeezed state generation, Review of Scientific Instruments 87, 103114 (2016).

42. Jin, XiaoliSu, JingZheng, Yaohui(*)Chen, ChaoyongWang,WenzhePeng, KunchiBalanced homodyne detection with high common mode rejection ratio based on parameter compensation of two arbitraryphotodiodesOptics Express20152318):23859-23866

43. Yang, WenhaiWang, YajunZheng, Yaohui(*)Lu, HuadongComparative study of the frequency-doubling performance on ring and linear cavity at short wavelength regionOptics Express20152315):19624-19633

44. Wang, YajunYang, WenhaiZhou, HaijunHuo, MeiruZheng, Yaohui(*)Temperature dependence of the fractional thermal load of Nd:YVO4 at 1064 nm lasing and its influence on laser performanceOptics Express20132115):18068-18078

45. Wang, YajunZheng, Yaohui(*)Shi, ZhuPeng, KunchiHigh-power single-frequency Nd:YVO4 green laser by self-compensation of astigmatismsLaser Physics Letters201297):506-510

46. Huadong LuJing SuYaohui Zheng(*)Kunchi PengPhysical conditions of single-longitudinal-mode operation for high-power all-solid-state lasersOptics Letters2014395):1117-1120

47. Zheng, Yaohui(*)Wang, YajunXie, ChangdePeng, KunchiSingle-Frequency Nd:YVO4 Laser at 671 nm With High-Output Power of 2.8 WIEEE Journal of Quantum Electronics2012481):67-72 期刊论文

48. Wang, YajunZheng, Yaohui(*)Xie, ChangdePeng, KunchiHigh-Power Low-Noise Nd:YAP/LBO Laser with Dual Wavelength OutputsIEEE Journal of Quantum Electronics2011477):1006-1013

49. Zhou, HaijunYang, WenhaiLi, ZhixiuLi, XuefengZheng, Yaohui(*)A bootstrapped, low-noise, and high-gain photodetector for shot noise measurementReview of Scientific Instruments2014851):013111-1-013111-5

50. Zhou, HaijunWang, WenzheChen, ChaoyongZheng, Yaohui(*)A low-noise, large-dynamic-range-enhanced amplifier based on JFET buffering input and JFET bootstrap structureIEEE Sensors Journal2015154):2101-2105

51. Zheng, YaohuiLu, HuadongLi, YongminZhang, KuanshouPeng, KunchiBroadband and rapid tuning of an all-solid-state single-frequency Nd : YVO4 laserApplied Physics B: Lasers and Optics2008903-4):485-488

52. Zheng, YaohuiLi, FengqinWang, YajunZhang, KuanshouPeng, KunchiHigh-stability single-frequency green laser with a wedge Nd:YVO4 as a polarizing beam splitterOptics Communications20102832):309-312

53. Zheng, YaohuiLu, HuadongLi, FengqinZhang, KuanshouPeng, KunchiFour watt long-term stable intracavity frequency-doubling Nd:YVO4 laser of single-frequency operation pumped by a fiber-coupled laser diodeApplied Optics20074622):5336-5339

54. Wang Ya-JunYang Wen-HaiZheng Yao-Hui(*)Peng Kun-ChiA compact Einstein-Podolsky-Rosen entangled light sourceChinese Physics B2015247)。

55. Zheng Yao-Hui(*)Wu Zhi-QiangHuo Mei-RuZhou Hai-JunGeneration of a continuous-wave squeezed vacuum state at 1.3 mu m by employing a home-made all-solid-state laser as pump sourceChinese Physics B2013229):094206-1-094206-4

56. Zheng Yao-Hui(*)Zhou Hai-JunWang Ya-JunWu Zhi-QiangSuppressing the preferential sigma-polarization oscillation in a high power Nd:YVO4 laser with wedge laser crystalChinese Physics B2013228):084207-1-084207-5

57. Zheng Yao-Hui(*)Wang Ya-JunPeng Kun-ChiA High-Power Single-Frequency 540 nm Laser Obtained by Intracavity Frequency Doubling of an Nd:YAP LaserChinese Physics Letters2012294):044208-1-044208-4

58. Hou, FeiyanYu, LinJia, Xiaojun(*)Zheng, YaohuiXie,ChangdePeng, KunchiExperimental generation of optical non-classical states of light with 1.34 mu m wavelengthEuropean Physical Journal D2011623):433-437

利情况:

1. 田龙,王嘉伟,刘震南,郑耀辉,一种可调节激光光束的集成精密光学透镜镜架,2021.04.12 2021.07.16 CN202110390039.9

2. 王雅君,武奕淼,郑耀辉,田龙,一种提取真空边模的装置和方法,2021.04.12 2021.07.30 CN202110390863.4

3. 王雅君,张文慧,孙瑜,郑耀辉,田龙,一种利用倍频腔抑制激光强度噪声的装置及其测量方法,2021.01.27 2021.06.11 CN202110113607.0

4. 郑耀辉,焦南婧,李瑞鑫,田龙,王雅君,一种减小剩余振幅调制的共振型电光调制器 2020.12.30 2022.03.18 CN202011614931.2

5. 郑耀辉,张文慧,彭堃墀,光学谐振腔,2018.03.13 2021.3.30 CN201810205343.X

6. 郑耀辉,王锦荣,张宏宇,赵子琳,田龙,王雅君,低噪声宽带高压放大器,2020.11.07 2021.02.23 CN202011233835.3

7. 王雅君,武奕淼,郑耀辉,田龙,一种快速精确测量光学腔自由光谱区的装置及方法,2020.09.22  2021.01.19 CN202011004925.5

8. 郑耀辉,田龙,史少平,王雅君,一种同时产生压缩态光场以及纠缠态光场的装置,2020.05.09 2020.0825 CN202010389156.9

9. 田龙,李庆回,郑耀辉,王雅君,一种基于多纠缠边带模式的量子通信装置,2020.04.30 2021.03.30 CN202010366016.X

10. 田龙,李瑞鑫,郑耀辉,一种集成精密光学镜架,2020.04.26  2020.11.06 CN202020653477.0

11. 郑耀辉,王锦荣,田龙,王雅君,一种平衡零拍探测器,2020.04.04 2021.03.30 CN202010261600.9

12. 田龙,郑耀辉,一种可调节激光光束方位角的精密光学镜架,2020.03.27 2021.02.02 CN202010231596.1

13. 郑耀辉,王锦荣,田龙,一种集成锁定支路的平衡零拍探测器,2019.11.07,2020.02.11 CN201911083458.7

14. 王雅君,李瑞鑫,郑耀辉,田龙,一种可温控的电光振幅调制器及测试方法,2019.11.21 2020.11.10 CN201911151557.4

15. 王雅君,张文慧 ,郑耀辉,彭堃墀,一种测量光学腔双共振温度条件的装置和方法,2018.12.07 2021.03.25 CN201811490989.3

16. 王雅君,张文慧,郑耀辉,彭堃墀,一种提高压缩光探测装置干涉效率的方法,2018.12.07 2020.04.17 CN201811490988.9

17. 田龙,郑耀辉,田宇航,王雅君,一种准连续量子压缩真空态光场产生装置,2019.04.28 2020.08.04 CN201910349725.4

18. 王雅君,王俊萍,张文慧,郑耀辉,一种相位自补偿的非经典光场发生器,2019.07.30 2020.06.12 CN201910362319.1

19. 郑耀辉,李志秀,田龙,一种稳定的连续变量量子纠缠源产生装置,2019.07.02 2020.05.26 CN201910588722.6

20. 田龙,郑耀辉,姚文秀,王雅君,一种光栅外腔反馈半导体激光器及其调节方法,2019.04.15 2020.04.17 CN201910300590.2

21. Device for reducing residual amplitude modulation, Yaohui Zheng, Xiaocong Sun, Yajun Wang, Kunchi Peng, 2017.04.24 2018.12.04  US10,146,072 B2

22. 王雅君,张文慧,郑耀辉 ,一种可快速精确调节两光学腔输出信号光干涉的装置,2017.11.14 2019.12.20 CN201711121394.6

23. 王雅君,张文慧,郑耀辉,一种可快速调节连续变量纠缠源信号光干涉的装置,2017.11.14 2019.12.10 CN201711122947.X

24. 郑耀辉,孙小聪,王雅君,彭堃墀,一种降低剩余振幅调制的装置,2017.3.22 2019.6.14 CN201710173451.9

25. 郑耀辉,孙小聪,王雅君,彭堃墀,一种测量光学参量振荡腔逃逸效率的方法,2017.1.10 2019.1.29 CN201710017218.1

26. 王雅君,郑耀辉,彭堃墀,一种测量非线性晶体吸收系数的方法,2016.5.17 2018.10.16 CN201610328935.1

27. 王雅君,郑耀辉,彭堃墀,一种非线性晶体热透镜焦距的测量方法,2016.5.17 2018.4.24 CN201610328103.X

28. 郑耀辉,李志秀,王雅君,彭堃墀,一种锁定两束同频率激光到任意位相的方法,2014.11.26 2017.10.17 CN201410690155.2

29. 郑耀辉,王雅君,彭堃墀,一种单频激光器波长比较的装置和方法,2014.10.20 2017.5.17 CN201410558996.8

30. 郑耀辉,彭堃墀,一种调节泵浦光与单共振光学参量腔模式匹配的方法,2014.9.5 2017.2.15 CN201410452706.1

31. 李志秀,郑耀辉,王雅君,彭堃墀,一种快速、精确地调节两束激光干涉的方法,2014.7.30 2017.1.11 CN201410371489.3

32. 郑耀辉,李志秀,彭堃墀,一种测量光学腔线宽的装置和方法,2014.9.5 2016.6.1 ,中国,CN201410452593.5

33. 郑耀辉,李志秀,彭堃墀,一种测量光学腔自由光谱范围的装置和方法,2014.9.5 2016.1.20,中国, CN201410452650.X

34. 郑耀辉,贾晓军,王文哲,张宽收,彭堃墀,一种连续变量量子纠缠源产生装置,2012.5.2-2031.10.14,中国,CN201110312978.8

35. 郑耀辉,王文哲,王雅君,周海军,彭堃墀,连续变量量子纠缠源中自动调节经典增益的装置和方法,2013.6.12-2033.3.14,中国,CN201310081935.2

36. 郑耀辉,王雅君,彭堃墀,一种像散自补偿固体激光器,2011.11.16-2031.5.26,中国,CN201110143305.4

37. 郑耀辉,王雅君,张宽收,李凤琴,彭堃墀,端面泵浦的高功率激光器,2010.6.2-2029.12.1,中国,CN200910227961.5

38. 郑耀辉,张宽收,顾世杰,李凤琴,彭堃墀,单频可调谐激光器,2006.5.10-2025.9.16,中国,CN200510012831.1

39. 郑耀辉,王雅君,石柱,郑晋玲,彭堃墀,一种激光器热焦距的测量方法,2011.9.7-2031.1.11,中国,CN201110008811.2

40. 郑耀辉,卢华东,李凤琴,张宽收,王尚廉,王文哲,彭堃墀,一种用于控制光学晶体温度的高温温度控制仪,2006.11.22-2026.6.13,中国,N200610012830.1

41. 郑耀辉,张宽收,彭堃墀,一种标准具控温装置,2008.1.16-2027.8.7,中国,CN200710062536.6

42. 郑耀辉,王雅君,彭堃墀,一种测量光学腔线宽的装置和方法,2016.3.10-2036.3.9,中国,CN201410452593.5

43. 王雅君,郑耀辉,杨文海,彭堃墀,一种连续变量量子纠缠源产生装置,2013.6.26-2033.4.11,中国,CN201310125998.3

44. 王文哲,郑耀辉,王尚廉,李凤琴,张宽收,低噪声高压放大器,2011.8.3-2031.3.30,中国,CN201110085853.6

45. 李凤琴,王尚廉,张宽收,郑耀辉,高压放大器,2007.10.10-2017.10.9,中国,200510012408.1

46. 郑耀辉,李志秀,彭堃墀,一种单频激光器波长比较的装置和方法,中国,CN201410558996.8

47. 郑耀辉,彭堃墀,一种调节泵浦光与单共振光学参量腔模式匹配的方法,中国,CN201410452706.1

48. 郑耀辉,李志秀,彭堃墀,一种锁定两束同频率激光到任意位相的方法,中国,CN201410690155.2

49. 李志秀,郑耀辉,王雅君,彭堃墀,一种快速、精确地调节两束激光干涉的方法,中国,CN201410371489.3

50. 张宽收,郑耀辉,彭堃墀,单频内腔倍频激光器,中国,CN200810079204.3。

51. 王文哲,郑耀辉,王尚廉,李凤琴,张宽收,低噪声高压放大器,2011.11.9-20 31.11.8,中国,201120097084.7

产品开发:

1、连续变量纠缠源产生装置,最高纠缠度达6dB(1080nm),属国内外首次实现

2、连续变量压缩光产生装置, 最高纠缠度达7.5dB(1064nm),属国内外首次实现

3、系列功率全固态连续单频绿光激光器(532 nm),最高输出功率25W,达当时同类激光器最高指标

4、全固态单频红光激光器(671 nm),最高输出功率2.8W,达当时同类激光器最高指标

5、全固态双波长输出单频Nd:YAP激光器(540 nm&1080nm),满足量子信息基础研究需要,国内外无同类产品

6、超低电子学噪声、高增益、大动态范围光电探测器,最低探测功率达5微瓦,50微瓦注入是的信噪比大于13dB

7、高共模抑制比平衡零拍探测器,共模抑制比达75.3dB,用于压缩/纠缠光探测

8、共振型电光探测器,用于反馈控制中光信号的探测。

专利转让情况:

1、郑耀辉,贾晓军,王文哲,张宽收,彭堃墀,一种连续变量量子纠缠源产生装置,2012.5.2-2031.10.14,中国,CN201110312978.8。 专利

2、郑耀辉,王雅君,彭堃墀,一种像散自补偿固体激光器,2011.11.16-2031.5.26,中国,CN201110143305.4。 专利

3、郑耀辉,王雅君,张宽收,李凤琴,彭堃墀,端面泵浦的高功率激光器,2010.6.2-2029.12.1,中国,CN200910227961.5。 专利

专利转化情况:

1、郑耀辉,贾晓军,王文哲,张宽收,彭堃墀,一种连续变量量子纠缠源产生装置,2012.5.2-2031.10.14,中国,CN201110312978.8。 专利

2、郑耀辉,王雅君,彭堃墀,一种像散自补偿固体激光器,2011.11.16-2031.5.26,中国,CN201110143305.4。 专利

3、郑耀辉,王雅君,张宽收,李凤琴,彭堃墀,端面泵浦的高功率激光器,2010.6.2-2029.12.1,中国,CN200910227961.5。 专利

4、郑耀辉,张宽收,顾世杰,李凤琴,彭堃墀,单频可调谐激光器,2006.5.10-2025.9.16,中国,CN200510012831.1。 专利

5、王文哲,郑耀辉,王尚廉,李凤琴,张宽收,低噪声高压放大器,2011.8.3-2031.3.30,中国,CN201110085853.6。 专利

6、李凤琴,王尚廉,张宽收,郑耀辉,高压放大器,2007.10.10-2017.10.9,中国,200510012408.1。 专利

7、张宽收,郑耀辉,彭堃墀,单频内腔倍频激光器,中国,N200810079204.3。专利