一种新颖的表面光波导型原子(或分子)分束器

提出了一种采用二元π位相板与柱面透镜组合而构成表面光波导型原子（或分子）分束器及其Mach-Zehnder干涉仪与X-分束器列阵的新方案，介绍了本方案的物理思想与基本原理，导出了光强分布、强度梯度、分束距离和分束路径的宽度与光学系统参数间的解析关系，并分析和讨论了本方案的潜在应用及其可行性. 研究表明，本方案设计新颖、光路简单，便于与其他元件组合构成具有表面微结构的集成原子（或分子）光学元器件及其全光型原子（或分子）芯片. 关键词： 原子（或分子）光波导 原子（或分子）分束器 原子（或分子）芯片 二元π位相板     

实现冷原子或冷分子囚禁的双层光阱列阵

提出了一种新颖的实现冷原子或冷分子囚禁的双层光阱方案,它由二元π相位板列阵和会聚透镜列阵所组成,用平面光波通过此光学系统时将在透镜焦平面两侧形成双层光阱.介绍了产生双层光阱的基本原理,分析了光阱光强分布、强度梯度等与光学系统参数间的关系,研究了双层光阱囚禁原子(或分子)的光学偶极势和自发散射速率(包括瑞利散射和拉曼散射)等.该方案不仅可用于多样品原子(或分子)的光学囚禁及全光型玻色一爱因斯坦凝聚(BEC),而且可用于制备新颖的双层2D光学晶格.     

通过圆孔衍射实现冷分子(或冷原子)囚禁的光学偶极阱

以单色标量波衍射理论为基础,研究单色平面波由圆孔衍射产生实现冷分子(或冷原子)光学囚禁的光阱。运用圆孔衍射理论分析讨论了光学偶极阱的光强分布、光学势及偶极力,并导出了有关光阱的几何参量、光强分布、强度梯度及其曲率与光学系统参量(如照明光波的波长、小孔的孔径)间的解析关系。研究表明,当激光功率与波长分别为P=500 W和λ=1.08μm,小孔半径a=20μm时,产生囚禁甲烷CH4分子的光阱光学势约为57.9μK。通过圆孔衍射可实现冷分子或冷原子囚禁,该方案不仅简单可行、操作方便,而且在冷分子物理、原子光学、分子光学和量子光学等领域中有着广阔的应用前景。     

用错位相位光栅产生的可调光学双阱

提出了用相位型错位光栅产生光学双阱的新方案.用平面光波(或TEM₀₀模式高斯光波)照射、正透镜聚焦,在透镜焦平面上产生的适用于冷原子或冷分子囚禁的多对可调光学双阱.计算和推导了双阱的光强分布、强度梯度以及光阱的几何参数与光学系统参数间的解析关系,研究了双阱到单阱三种不同的演化过程.同时还计算了光学双阱囚禁冷原子的光学偶极势和光子散射速率.研究发现,该方案不仅简单可行、操作方便,而且在原子物理、原子光学、分子光学和量子光学领域中有着广阔的应用前景. 关键词： 原子光学 相位光栅 光学双阱 冷原子囚禁     

一种新颖的表面空心微光阱阵列

提出了采用四台阶相位光栅与微透镜阵列组合产生一种新颖的表面空心微光阱阵列的方案，研究了表面空心微光阱阵列的光强分布，计算了相应的光学囚禁势，并讨论了该微光阱阵列在原子分子光学中的潜在应用.研究表明当用1W的YAG激光照射时，在1cm²面积上可产生近10⁴个空心光阱，每个光阱具有较小的囚禁体积和较大的有效光强及其强度梯度，对⁸⁵Rb原子的光学囚禁势可达190μK.如此深的光阱足以囚禁冷原子或冷分子，并可用于实现全光型原子或分子玻色-爱因斯坦凝聚，甚至制备新颖的光学晶格等. 关键词： 空心光阱 冷原子或冷分子 光学晶格     

采用四根单模光纤束实现消逝波原子(或分子)波导的理论分析

提出了一种利用四根亚微米单模光纤束实现冷原子(或冷分子)波导的新方案，计算了四光纤束内空心区域的消逝波光场及其光学囚禁势.研究表明这种蓝失谐的空心消逝波光场同样可用于实现冷原子(或冷分子)的激光波导，而且与传统的中空光纤原子波导方案相比，不仅简单方便，造价低廉，而且更容易实现冷原子物质波的高效单模波导. 关键词： 单模光纤 消逝波 原子(或分子)波导     

采用Damman光栅实现冷原子或冷分子囚禁的光阱阵列

提出了一种采用Damman光栅和球面透镜组合光学系统产生二维光阱阵列的新方案. 在使用红失谐高斯激光束照射的条件下，推导了计算光阱阵列的周期、光强分布、光强梯度和光阱几何参数的经验公式，讨论了此光阱阵列的特点以及在原子光学和分子光学中的应用. 研究结果表明，这种光阱阵列方案比已有的光阱阵列方案更为简单可行、操作方便，非常适用于冷原子或冷分子的阵列囚禁，以及制备新颖的光学晶格. 关键词： 冷原子或冷分子 光阱阵列 Damman光栅 光偶极势     

表面空心光束列阵的产生及其在原子分子光学中的应用

本文提出了一种采用柱面微透镜列阵与二元位相型光栅组合并利用两束平面光波照明在芯片表面附近产生一维聚焦暗中空光束原子或分子波导列阵的新方案,计算与分析了暗中空光管列阵的光强分布和导引85Rb冷原子的光学势分布,讨论了暗中空光管的特征参数与光学系统参数的关系.结果表明:若用波长为0.78 μm,光强为7.0×103 W/m2和蓝失谐频率为10 GMHz的激光照明时,对于85Rb原子,每一束暗中空光束的有效光学势为0.23 mK(这远高于标准光学粘胶中85Rb冷原子的温度～20 μK),相应的横向暗斑尺寸为4.4 μm.此外,在该方案中,如果改变入射光的方向,则可使波导列阵在芯片表面上移动,以实现冷原子的一维操作与控制.最后,本文还讨论了本方案的实验可行性以及在原子光学和分子光学领域中的潜在应用.     

冷原子或冷分子囚禁的可控制光学双阱

提出了一种采用单光束照明二元π相位板与透镜组合系统产生的适用于冷原子与分子囚 禁的可控制光学双阱方案.计算了双阱的光强分布，研究了双阱到单阱的演化过程，并导出了双阱几何参数、光强分布、强度梯度及其曲率与光学系统参数间的解析关系.研究发现， 通过相对移动二元相位板可实现光学双阱到单阱的连续双向演化，得到了双阱间距与相位板移动距离的关系.该方案不仅简单可行、操作方便，而且在原子物理、原子光学、分子光学和量子光学领域中有着广阔的应用前景. 关键词： 二元相位板 可控制光学双阱 原子囚禁 原子光学 分子光学     

实现冷原子(冷分子)囚禁的可控制光学双阱的产生及其实验研究

简单介绍了实现冷原子或冷分子囚禁的可控制光学双阱的实验方案，报道了二元π相位板的制作方法及其产生可控制光学双阱的实验结果.分析了光学双阱参数(如空间位置、双阱中心间距、相对光强分布等)与π相位板相位偏差的关系.从理论和实验上研究了由于二元π相位板的刻蚀厚度误差引起的光学双阱光强变化及其双阱到单阱的演化规律，得到了实验与理论基本一致的结果. 关键词： 二元相位板 可控制光学双阱 冷原子囚禁 冷分子囚禁     

Two-dimensional novel optical lattices with multi-well traps for cold atoms or molecules

We propose some new schemes to constitute two-dimensional (2D) array of multi-well optical dipole traps for cold atoms (or molecules) by using an optical system consisting of a binary π-phase grating and a 2D array of rectangle microlens. We calculate the intensity distribution of each optical well in 2D array of multi-well traps and its geometric parameters and so on. The proposed 2D array of multi-well traps can be used to form novel 2D optical lattices with cold atoms (or molecules), and form various novel optical crystals with cold atoms (or molecules), or to perform quantum computing and quantum information processing on an atom chip, even to realize an array of all-optical multi-well atomic (or molecular) BoseEinstein condensates (BECs) on an all-optical integrated atom (or molecule) chip.     

Atom funnel running with evanescent light generated by a thick hollow light beam

The use of a hollow light beam reduces the loss of atoms inside and outside an evanescent-light funnel. Therefore, we superimpose an LG₀₁ beam with a small hole onto a doughnut beam with a large outer diameter and couple the resultant hollow light beam to the 240-μm-wide outlet of an inverted trigonal-pyramidal funnel. Compared to the case where a Gaussian light beam is employed for generation of evanescent light, the flux intensity of the output cold ⁸⁷Rb atoms rises 13-fold when the inner diameter of the 4.5-mm wide hollow light beam is 1.7 times as large as the size of the outlet under optimal blue-detuning conditions.     

Microfabricated evanescent-light funnel with high-intensity cold atom flux

We process a silicon-on-insulator substrate into a funnel with a 25-μm-side square-shaped outlet by photolithography and anisotropic chemical etching. The funnel is utilized to form a cold atomic beam by means of reflection and cooling on repulsive evanescent light. Monte Carlo simulations show that the flux intensity of emitted cold Rb atoms reaches 10¹² cm⁻² s⁻¹. The mean horizontal velocity is estimated to be below 10 cm/s, while the mean vertical velocity decreases in proportion to the outlet side. The evanescent-light funnel can be developed to concentrate 80% of Rb atoms falling from a standard magneto-optical trap.     

A cold cesium atomic beam produced out of a pyramidal funnel

We have built an atomic funnel which produces a slow and cold cesium atomic beam. The atomic funnel is based on a pyramidal Magneto Optical Trap (MOT) with a small hole at its apex. Characterization of the funnel operation has been carried out by fluorescence emission and absorption spectroscopy, and optical time of flight (TOF) methods. The atomic beam has a longitudinal velocity in the range 8–12 m/s and a spread less than 1.5 m/s. The transverse temperature is close to the Doppler limit. Typically, an atom flux 4×10⁹ atoms/s is attained. These features, combined with the compactness and simplicity of the experimental arrangement, make this system an ideal source for experiments in atom lithography and atom optics.     

Long-range perturbations produced by a localized packet of ion-acoustic waves in a collisionless plasma

We demonstrate the in situ detection of cold ⁸⁷Rb atoms near a dielectric surface using the absorption of a weak, resonant evanescent wave. We have used this technique in time of flight experiments determining the density of atoms falling on the surface. A quantitative understanding of the measured curve was obtained using a detailed calculation of the evanescent intensity distribution. We have also used it to detect atoms trapped near the surface in a standing-wave optical dipole potential. This trap was loaded by inelastic bouncing on a strong, repulsive evanescent potential. We estimate that we trap 1.5×10⁴ atoms at a density 100 times higher than the falling atoms. Received 14 May 2002 Published online 8 October 2002 RID="a" ID="a"e-mail: spreeuw@science.uva.nl     

Axially symmetric hollow beams using refractive conical lenses

We explore the possibility of producing several beam shapes with conical or cylindrical geometry using conical lenses. We discuss optical schemes for generation of hollow laser beams; with 3D intensity distribution surrounding all directions, a dark core region can be obtained. These optical fields are important for the confinement of cold atoms in 2D or 3D blue dipole potentials.     

Electrostatic guiding of cold polar molecules on a chip

We propose a novel scheme to guide cold polar molecules on the surface of an insulating substrate (i.e. a chip) using an electrostatic field generated by the combination of a pair of parallel charged wires and a grounded metal plate. The spatial distributions of the electric fields from the above charged-wire layout and their Stark potentials for cold CO molecules and dipole forces are calculated, and the relationships between the electric field and the geometric parameters of our charged-wire system are analyzed. Our study shows that our charged-wire scheme can be used to guide cold polar molecules in the weak-field-seeking state, and to construct various molecular optical elements, such as a molecular funnel, a molecular beam splitter and a molecular interferometer and so on, to form various integrated molecular optical elements and their molecular chips, and even to generate a continuous wave (CW) cold molecular beam by using a low-pass energy filter based on bent two-wire guiding.