Optical Dipole Traps for Neutral Atoms
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TL;DR: In this article, optical dipole traps for neutral atoms have been used for storage and trapping of charged and neutral atoms in the vast energy range from elementary particles to ultracold atomic quantum matter.
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Abstract: Publisher Summary This chapter discusses optical dipole traps for neutral atoms Methods for storage and trapping of charged and neutral particles have very often served as the experimental key to great scientific advances, covering physics in the vast energy range from elementary particles to ultracold atomic quantum matter It describes the basic physics of dipole trapping in fardetuned light, the typical experimental techniques and procedures, and the different trap types currently available, along with their specific features In the experiments discussed, optical dipole traps have already shown great promise for a variety of different applications Of particular importance is the trapping of atoms in the absolute internal ground state, which cannot be trapped magnetically In this state, inelastic binary collisions are completely suppressed for energetic reasons In this respect, an ultracold cesium gas represents a particularly interesting situation, because Bose–Einstein condensation seems attainable only for the absolute ground state Therefore, an optical trap may be the only way to realize a quantum-degenerate gas of Cs atoms Further, optical dipole traps can be seen as storage devices at the low end of the presently explorable energy scale Future experiments exploiting the particular advantages of these traps can reveal interesting new phenomena
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Citations
Spinor Bose-Einstein comagnetometer and interhyperfine interactions in 87Rb
Pau Gómez Kabelka
TL;DR: La primera realització d’un comagnetometer en el ultracold regim és presentada. El comagnetometer utilitza dos magnetometres per cancelar el camp magnètic extern i discernir interaccions que afecten de forma diferent els seus constituents.
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Trapping Ions with Light Fields
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TL;DR: In this article, the authors discuss the complications arising from the interaction of ions with ambient electric fields, the consequential prerequisites, and experimental techniques for carrying out optical ion trapping experiments.
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Long-distance optical-conveyor-belt transport of ultracold <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mmultiscripts><mml:mi>Cs</mml:mi><mml:mprescripts /><mml:none /><mml:mn>133</mml:mn></mml:mmultiscripts></mml:math> and <mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"
Alexander Matthies,Jonathan M. Mortlock,L. A. McArd,Adarsh P. Raghuram,A. D. Innes,Philip D. Gregory,Sarah L. Bromley,Simon L. Cornish +7 more
- 15 Feb 2024
TL;DR: Ultracold cesium and rubidium atoms are transported over long distances using an optical conveyor belt formed by two counter-propagating beams with a controllable frequency difference. Transport efficiency up to 75% is achieved.
References
Observation of Bose-Einstein Condensation in a Dilute Atomic Vapor
TL;DR: A Bose-Einstein condensate was produced in a vapor of rubidium-87 atoms that was confined by magnetic fields and evaporatively cooled and exhibited a nonthermal, anisotropic velocity distribution expected of the minimum-energy quantum state of the magnetic trap in contrast to the isotropic, thermal velocity distribution observed in the broad uncondensed fraction.
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TL;DR: In this article, Bose-Einstein condensation of sodium atoms was observed in a novel trap that employed both magnetic and optical forces, which increased the phase-space density by 6 orders of magnitude within seven seconds.
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Acceleration and trapping of particles by radiation pressure
TL;DR: In this paper, it is hypothesized that similar acceleration and trapping are possible with atoms and molecules using laser light tuned to specific optical transitions, and the implications for isotope separation and other applications of physical interest are discussed.
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Evidence of Bose-Einstein Condensation in an Atomic Gas with Attractive Interactions
TL;DR: Evidence for Bose-Einstein condensation of a gas of spin-polarized {sup 7}Li atoms is reported, and phase-space densities consistent with quantum degeneracy are measured for temperatures in the range of 100 to 400 nK.
Optical Resonance and Two-level Atoms
TL;DR: In this paper, optical resonance and two-level atoms have been studied in terms of two level atoms, and two level atoms have been shown to have similar properties to two-layer atoms.
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