Laser cooling

美 [ˈleɪzər ˈkuːlɪŋ]英 [ˈleɪzə(r) ˈkuːlɪŋ]
  • 网络激光冷却;雷射冷却
Laser coolingLaser cooling
  1. Laser cooling and it 's applications in science and technology

    激光冷却及其在科学技术中的应用

  2. Laser cooling of an atomic beam with high efficiency

    高效率激光冷却原子束

  3. Review , Thermodynamic Analysis , and Prediction on Laser Cooling Technique

    关于激光制冷技术的回顾、热力学分析与展望

  4. The Best Pump Frequency and the Most Cooling Efficiency in Laser Cooling with Energy Transfer Mechanism

    能量传递制冷机制中激光制冷的最佳泵浦频率和最大制冷效率

  5. Theoretical Study on Laser Cooling of Tm ~( 3 + ) - doped Materials

    Tm~(3+)离子掺杂材料激光制冷的理论分析

  6. Laser cooling techniques , can achieve ultra-low temperature .

    通过激光冷却技术,可以实现超低温度。

  7. New Mechanisms for Laser Cooling of Atoms

    激光冷却原子新机制

  8. Laser cooling and trapping has obtained very fruitful results in recent twenty years .

    近二十几年来激光冷却原子的研究取得了丰硕的成果。

  9. Theoretical analysis of laser cooling of Tm ~ ( 3 + ) - doped fiber

    Tm~(3+)掺杂光纤激光制冷的理论分析

  10. Research of military laser cooling fluids

    军用激光器冷却液的研制

  11. Research on Laser Cooling in Thulium - Doped Materials

    Tm~(3+)掺杂材料激光冷却的研究

  12. The results provide a basis for optimizing the chromium beam collimation by laser cooling .

    这些结果为优化调整铬原子束激光冷却准直实验提供了依据。

  13. Rhodamine B doped PMMA & A potential material in laser cooling of solid

    一种潜在的激光制冷介质-罗丹明B掺杂PMMA

  14. Application of Laser Cooling in Atomic Beam Imaging by a Hexapole Magnetic Lens

    激光冷却在原子束六极磁透镜技术中的应用

  15. Laser cooling and trapping of gas atoms and molecules

    激光冷却和捕陷气体原子或分子

  16. On the one hand makes the study of laser cooling and manipulation of matter at extremely low temperature system possible .

    一方面激光冷却技术使得研究并操控极低温度下物质体系成为可能。

  17. The system has significant practice value of the object recognition , atmosphere supervising and laser cooling of atoms etc.

    该系统在目标识别、大气环境监测、激光冷却原子等应用中具有重要的价值。

  18. In recent years , laser cooling of solid materials based on the anti-Stokes fluorescence has obtained fast development .

    近年来,基于反斯托克斯荧光制冷的固体材料激光冷却技术得到了快速发展。

  19. UV laser cooling of magnesium atomic beam

    紫外激光冷却镁原子

  20. Laser cooling and trapping of Rb atoms was realized .

    实现了Rb原子的激光冷却与囚禁。

  21. Theory and New Method of Laser Cooling of Atoms by Spatial Doppler Tuning and Effects of Monochromatic Velocity

    利用空间多普勒调谐技术冷却原子及其速度单一化

  22. The cesium atomic fountain used laser cooling and trapping is a new generation primary frequency standard .

    应用激光冷却与囚禁的铯原子喷泉是新一代的频率基准。

  23. Laser cooling methods and atom trapping an introduction to the 1997 Nobel Prize in Physics

    激光冷却与捕陷原子的方法&1997年诺贝尔物理奖介绍

  24. The results show that the larger of power and the bigger of spot size , the better of laser cooling .

    结果表明:激光冷却场功率越大,纵向光斑尺寸越大,激光冷却效果越好,并出现饱和现象。

  25. The control process for the laser cooling and trapping atom experimental system based on virtual instrument is explained in details .

    第三部分着重分析了激光冷却与俘获原子实验过程的控制,详细描述了我们研制基于虚拟仪器的激光冷却原子实验控制系统的过程。

  26. Laser Cooling and Trapping for the Neutral Atoms

    激光冷却和囚禁中性原子

  27. The shortest size of the laser cooling beam is computed theoretically to be 13.7 ? mm .

    根据理论计算出准直激光束的最小尺寸为13.7mm。

  28. Laser cooling with phase-change heat transfer in microgrooves and Tec

    微槽群相变与热电制冷结合的激光器冷却系统

  29. In this paper , a simple setup of laser cooling and trapping of Rb atom is presented .

    介绍了一套用于Rb原子的冷却和俘获的实验装置。

  30. The energy gap of two states determines two important elements in laser cooling , quantum efficiency and multiphonon relaxation rate .

    能级间距决定了对激光制冷至关重要的两个因素:量子效率和无辐射跃迁速率。