Rubidium Vapor(铷蒸气)研究综述
Rubidium Vapor 铷蒸气 - We investigate Lévy flight of light in a hot rubidium vapor collisional-broadened by 50 torr of He gas. [1] We experimentally demonstrate chip-scale optical pumping of Rubidium vapor based on novel atomic-cladded tapered nano-waveguides with different buffer-gas pressures. [2] Here we make use of 3 infrared lasers to realize a Rydberg EIT system in a thermal rubidium vapor cell. [3] We discuss the experimental research of an optical resonant saturation of a dipole–dipole-broadened atomic transition in the high-density rubidium vapor. [4] We conclude the paper with a proposal for experimentally investigating the four-photon excitation process to the Rydberg state in thermal rubidium vapor. [5] We report on the optical storage of Ince-Gaussian modes in a warm rubidium vapor cell based on electromagnetically induced transparency protocol, and we also qualitatively analyze how atomic diffusion affects the retrieved beams after storage. [6] Our source is based on four-wave mixing in hot rubidium vapor, requiring no laser cooling or optical cavities, and generates single photons with high rate and low noise. [7] With substantial improvements on the optical arrangement, we show that significant enhancement of the magneto-optical rotation effect in rubidium vapor can be achieved without using complex and expensive heterodyne polarimetric methods. [8] A rubidium vapor cell with octade-cyltrichlorosilane (OTS) antirelaxation coating has been used in our experiment to produce narrow linewidth magnetic resonances. [9] Welch, "Absorption resonance and large negative delay in rubidium vapor with a buffer gas", J. [10] We demonstrate gain without inversion towards lasing in a lossy medium, based on atomic interference in Rubidium vapor confined in microscale vapor cell. [11] We present the results of 10 years of research related to the development of a Rubidium vapor cell clock based on the principle of pulsed optical pumping (POP). [12] We present a practically realizable scheme, where intensity squeezed beams are generated by a seeded four-wave mixing process in an atomic rubidium vapor cell. [13] In this study, octadecyltrichlorosilane (OTS) was coated in spherical rubidium vapor cells fabricated using borosilicate glass with two stems as anti-relaxation coatings. [14] For this purpose, we design and fabricate atomic evanescent Rb vapor cells and examine the effect of polarization changes of evanescent waves, depending on the propagation direction of evanescent waves in anisotropic rubidium vapor media under different external magnetic field configurations theoretically and experimentally. [15] We measure this variation in optical response using a Rubidium vapor at a 15GHz RF carrier frequency. [16]我们研究了被 50 托氦气碰撞加宽的热铷蒸气中的 Lévy 光飞行。 [1] 我们实验证明了基于具有不同缓冲气体压力的新型原子包层锥形纳米波导的铷蒸气的芯片级光学泵浦。 [2] 在这里,我们利用 3 个红外激光器在热铷蒸汽电池中实现了 Rydberg EIT 系统。 [3] 我们讨论了高密度铷蒸气中偶极-偶极展宽原子跃迁的光学共振饱和的实验研究。 [4] 我们在论文结束时提出了一项建议,以实验研究热铷蒸气中四光子激发到里德堡态的过程。 [5] 我们报告了基于电磁感应透明协议的暖铷蒸气电池中因斯高斯模式的光学存储,我们还定性地分析了原子扩散如何影响存储后的检索光束。 [6] 我们的光源基于热铷蒸气中的四波混合,不需要激光冷却或光学腔,并产生高速率和低噪声的单光子。 [7] 随着光学布置的显着改进,我们表明可以在不使用复杂且昂贵的外差极化法的情况下实现铷蒸气中磁光旋转效应的显着增强。 [8] 我们的实验中使用了具有八烷基三氯硅烷 (OTS) 抗松弛涂层的铷蒸气电池来产生窄线宽磁共振。 [9] Welch,“缓冲气体铷蒸气的吸收共振和大的负延迟”,J. [10] 基于限制在微尺度蒸汽电池中的铷蒸汽的原子干扰,我们展示了在有损介质中没有反转激光的增益。 [11] 我们展示了 10 年来与基于脉冲光泵 (POP) 原理的铷蒸汽电池时钟开发相关的研究结果。 [12] 我们提出了一个实际可实现的方案,其中强度压缩光束由原子铷蒸气电池中的种子四波混合过程产生。 [13] 在这项研究中,十八烷基三氯硅烷 (OTS) 被涂覆在球形铷蒸气电池中,该电池使用具有两个茎的硼硅酸盐玻璃作为抗松弛涂层。 [14] 为此,我们设计和制造了原子倏逝Rb蒸气电池,并从理论上和实验上检验倏逝波偏振变化的影响,这取决于倏逝波在不同外部磁场配置下各向异性铷蒸气介质中的传播方向。 [15] 我们使用 15GHz RF 载波频率的铷蒸气测量光学响应的这种变化。 [16]
Hot Rubidium Vapor
We investigate Lévy flight of light in a hot rubidium vapor collisional-broadened by 50 torr of He gas. [1] Our source is based on four-wave mixing in hot rubidium vapor, requiring no laser cooling or optical cavities, and generates single photons with high rate and low noise. [2]我们研究了被 50 托氦气碰撞加宽的热铷蒸气中的 Lévy 光飞行。 [1] 我们的光源基于热铷蒸气中的四波混合,不需要激光冷却或光学腔,并产生高速率和低噪声的单光子。 [2]
Thermal Rubidium Vapor
Here we make use of 3 infrared lasers to realize a Rydberg EIT system in a thermal rubidium vapor cell. [1] We conclude the paper with a proposal for experimentally investigating the four-photon excitation process to the Rydberg state in thermal rubidium vapor. [2]在这里,我们利用 3 个红外激光器在热铷蒸汽电池中实现了 Rydberg EIT 系统。 [1] 我们在论文结束时提出了一项建议,以实验研究热铷蒸气中四光子激发到里德堡态的过程。 [2]
rubidium vapor cell
Here we make use of 3 infrared lasers to realize a Rydberg EIT system in a thermal rubidium vapor cell. [1] We report on the optical storage of Ince-Gaussian modes in a warm rubidium vapor cell based on electromagnetically induced transparency protocol, and we also qualitatively analyze how atomic diffusion affects the retrieved beams after storage. [2] A rubidium vapor cell with octade-cyltrichlorosilane (OTS) antirelaxation coating has been used in our experiment to produce narrow linewidth magnetic resonances. [3] We present the results of 10 years of research related to the development of a Rubidium vapor cell clock based on the principle of pulsed optical pumping (POP). [4] We present a practically realizable scheme, where intensity squeezed beams are generated by a seeded four-wave mixing process in an atomic rubidium vapor cell. [5] In this study, octadecyltrichlorosilane (OTS) was coated in spherical rubidium vapor cells fabricated using borosilicate glass with two stems as anti-relaxation coatings. [6]在这里,我们利用 3 个红外激光器在热铷蒸汽电池中实现了 Rydberg EIT 系统。 [1] 我们报告了基于电磁感应透明协议的暖铷蒸气电池中因斯高斯模式的光学存储,我们还定性地分析了原子扩散如何影响存储后的检索光束。 [2] 我们的实验中使用了具有八烷基三氯硅烷 (OTS) 抗松弛涂层的铷蒸气电池来产生窄线宽磁共振。 [3] 我们展示了 10 年来与基于脉冲光泵 (POP) 原理的铷蒸汽电池时钟开发相关的研究结果。 [4] 我们提出了一个实际可实现的方案,其中强度压缩光束由原子铷蒸气电池中的种子四波混合过程产生。 [5] 在这项研究中,十八烷基三氯硅烷 (OTS) 被涂覆在球形铷蒸气电池中,该电池使用具有两个茎的硼硅酸盐玻璃作为抗松弛涂层。 [6]