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1. An optical chip for a single atom single photon source

   Zhang, Jin; Oh, Eunji; Yu, Zhaoning; Mehlenbacher, Brandon; Kats, Mikhail; Goldsmith, Randall; Saffman, Mark (June 2021, DAMOP 2021, Bulletin of the American Physical Society)

   We report on progress towards a single atom, single photon source using a fiber connected optical chip. Quantum experiments with cold atoms are burdened by the complexity of the experimental apparatus. Using fiber connectorized optics and a grating MOT suitable for cooling Rb atoms we fabricate a pre-aligned device usable as a single photon source for quantum communication experiments. The device integrates a grating MOT with a single beam dipole trap produced by a fiber and GRIN lens combination. MOT atoms are loaded into the dipole trap and then used as a source of single photons which are collected by the same optical fiber. We will report on details of the fabrication of the optical chip, experimental characterization, and progress towards generating high purity single photons. 

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2. Optical two-dimensional coherent spectroscopy of cold atoms

   https://doi.org/10.1364/OL.478793  

   Liang, Danfu; Savio_Rodriguez, Lexter; Zhou, Haitao; Zhu, Yifu; Li, Hebin (December 2022, Optics Letters)

   We report an experimental demonstration of optical two-dimensional coherent spectroscopy (2DCS) in cold atoms. The experiment integrates a collinear 2DCS setup with a magneto-optical trap (MOT), in which cold rubidium (Rb) atoms are prepared at a temperature of approximately 200 µK and a number density of 10¹⁰cm⁻³. With a sequence of femtosecond laser pulses, we first obtain one-dimensional second- and fourth-order nonlinear signals and then acquire both one-quantum and zero-quantum 2D spectra of cold Rb atoms. The capability of performing optical 2DCS in cold atoms is an important step toward optical 2DCS study of many-body physics in cold atoms and ultimately in atom arrays and trapped ions. Optical 2DCS in cold atoms/molecules can also be a new avenue to probe chemical reaction dynamics in cold molecules. 

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3. A reconfi gurable blue-detuned lattice for neutral atom quantum computing

   Graham, Trent; Poole, Cody; Xiaoyu, Jiang; Marra, Alphonse; Grinkemeyer, Brandon; Hickman, Garrett; Cherek, Josh; Ebert, Matthew; Saffman, Mark (May 2019, 50th Annual Meeting of the APS Division of Atomic, Molecular and Optical Physics APS Meeting)

   We present recent progress towards building a neutral atom quantum computer. We use a new design for a blue-detuned optical lattice to trap single Cs atoms. The lattice is created using a combination of diffractive elements and acousto-optic deflectors (AODs) which give a reconfigurable set of cross-hatched lines. By using AODs, we can vary the number of traps and size of the trapping regions as well as eliminate extraneous traps in Talbot planes. Since this trap uses blue-detuned light, it traps both ground state atoms and atoms excited to the Rydberg state; moreover, by tuning the size of the trapping region, we can make the traps “magic” for a selected Rydberg state. We use an optical tweezer beam for atom rearrangement. When loading atoms into the array, trap sites randomly contain zero or one atoms. Atoms are then moved between different trapping sites using a red-detuned optical tweezer. Optimal atom rearrangement is calculated using the “Hungarian Method”. These rearrangement techniques can be used to create defect-free sub-lattices. Lattice atoms can also be used as a reservoir for a set of selected sites. This allows quick replacement of atoms, and increased data rate, without reloading from a MOT. 

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4. A reconfi gurable blue-detuned lattice for neutral atom quantum computing

   GRAHAM, T.; POOLE, C; JIANG, X; MARRA, Z; GRINKEMEYER, B; HICKMAN, G; CHEREK, J; EBERT, M; SAFFMAN, M. (May 2019, DAMOP 2019)

   We present recent progress towards building a neutral atom quantum computer. We use a new design for a blue-detuned optical lattice to trap single Cs atoms. The lattice is created using a combination of diffractive elements and acousto-optic deflectors (AODs) which give a reconfigurable set of cross-hatched lines. By using AODs, we can vary the number of traps and size of the trapping regions as well as eliminate extraneous traps in Talbot planes. Since this trap uses blue-detuned light, it traps both ground state atoms and atoms excited to the Rydberg state; moreover, by tuning the size of the trapping region, we can make the traps “magic” for a selected Rydberg state. We use an optical tweezer beam for atom rearrangement. When loading atoms into the array, trap sites randomly contain zero or one atoms. Atoms are then moved between different trapping sites using a red-detuned optical tweezer. Optimal atom rearrangement is calculated using the “Hungarian Method”. These rearrangement techniques can be used to create defect-free sub-lattices. Lattice atoms can also be used as a reservoir for a set of selected sites. This allows quick replacement of atoms, and increased data rate, without reloading from a MOT. 

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5. Diffractive chips for magneto-optical trapping of two atomic species

   https://doi.org/10.1364/CLEO_SI.2020.STh4G.7  

   Yu, Zhaoning; Hickman, Garrett; Saffman, Mark; Kats, Mikhail A. (January 2020, Conference on Lasers and Electro-Optics, OSA Technical Digest)

   We investigate diffractive grating chips that can be used as part of a magneto-optical trap (MOT) to trap both Rb and Cs atoms with a single input beam for each atom species. 

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