Effective Potential for Ultracold Atoms at the Zero Crossing of a Feshbach Resonance

N. Zinner
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引用次数: 4

Abstract

We consider finite-range effects when the scattering length goes to zero near a magnetically controlled Feshbach resonance. The traditional effective-range expansion is badly behaved at this point, and we therefore introduce an effective potential that reproduces the full T-matrix. To lowest order the effective potential goes as momentum squared times a factor that is well defined as the scattering length goes to zero. The potential turns out to be proportional to the background scattering length squared times the background effective range for the resonance. We proceed to estimate the applicability and relative importance of this potential for Bose-Einstein condensates and for two-component Fermi gases where the attractive nature of the effective potential can lead to collapse above a critical particle number or induce instability toward pairing and superfluidity. For broad Feshbach resonances the higher order effect is completely negligible. However, for narrow resonances in tightly confined samples signatures might be experimentally accessible. This could be relevant for suboptical wavelength microstructured traps at the interface of cold atoms and solid-state surfaces.
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费什巴赫共振零交叉处超冷原子的有效势
我们考虑了当散射长度趋近于零时的有限范围效应。传统的有效范围展开在这一点上表现很差,因此我们引入了一个再现完整t矩阵的有效势。最低阶的有效势等于动量的平方乘以一个因子,这个因子在散射长度趋于零时被很好地定义。电势与背景散射长度的平方乘以背景谐振有效范围成正比。我们继续估计该势对玻色-爱因斯坦凝聚体和双组分费米气体的适用性和相对重要性,其中有效势的吸引性质可能导致超过临界粒子数的坍缩或诱导对和超流体的不稳定性。对于宽费什巴赫共振,高阶效应完全可以忽略不计。然而,对于窄共振在严格限制的样品签名可能是实验可获得的。这可能与冷原子和固体表面界面的亚光学波长微结构陷阱有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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Multi-electron atoms Interaction of one-electron atoms with radiation One-electron atoms Molecules: general features Electronic structure of molecules
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