量子冷原子真空标准中背景气体碰撞导致冷原子损失率的精确测量

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY AVS quantum science Pub Date : 2023-02-23 DOI:10.1116/5.0147686
D. Barker, J. Fedchak, J. Kłos, J. Scherschligt, A. A. Sheikh, E. Tiesinga, S. Eckel
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引用次数: 0

摘要

我们给出了超冷7Li和87Rb与室温He, Ne, N2, Ar, Kr和Xe碰撞的热化碰撞速率系数的测量结果。在我们的实验中,我们使用一个组合流量计和动态膨胀系统,一个真空计量标准,来设定一个已知的数字密度在室温背景气体附近的磁捕获7Li或87Rb云。每次与背景原子或分子的碰撞都会使7Li或87Rb原子从其陷阱中移除,原子损失率随背景气体密度的变化用于确定热化损失率系数,其分数标准不确定度优于7Li的1.6%和87Rb的2.7%。我们在测量结果和最近的损失率系数的量子散射计算[Kłos和Tiesinga, J. Chem]之间发现了一致性——小于1的等效程度。物理学报,158,014308(2023)],除了7Li和87Rb与Ar碰撞的损失率系数。然而,所有其他研究系统的理论和实验之间的一致性提供了验证,即使用冷原子对真空压力的基于量子的测量也可以作为真空压力的主要标准,我们称之为冷原子真空标准。
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Accurate measurement of the loss rate of cold atoms due to background gas collisions for the quantum-based cold atom vacuum standard
We present the measurements of thermalized collisional rate coefficients for ultra-cold 7Li and 87Rb colliding with room-temperature He, Ne, N2, Ar, Kr, and Xe. In our experiments, a combined flowmeter and dynamic expansion system, a vacuum metrology standard, is used to set a known number density for the room-temperature background gas in the vicinity of the magnetically trapped 7Li or 87Rb clouds. Each collision with a background atom or molecule removes a 7Li or 87Rb atom from its trap, and the change in the atom loss rate with background gas density is used to determine the thermalized loss rate coefficients with fractional standard uncertainties better than 1.6% for 7Li and 2.7% for 87Rb. We find consistency—a degree of equivalence of less than one—between the measurements and recent quantum-scattering calculations of the loss rate coefficients [Kłos and Tiesinga, J. Chem. Phys. 158, 014308 (2023)], with the exception of the loss rate coefficient for both 7Li and 87Rb colliding with Ar. Nevertheless, the agreement between theory and experiment for all other studied systems provides validation that a quantum-based measurement of vacuum pressure using cold atoms also serves as a primary standard for vacuum pressure, which we refer to as the cold-atom vacuum standard.
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CiteScore
9.90
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