Full-dimensional quantum scattering calculations on ultracold atom-molecule collisions in magnetic fields: The role of molecular vibrations

M. Morita, J. Kłos, T. Tscherbul
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引用次数: 4

Abstract

Rigorous quantum scattering calculations on ultracold molecular collisions in external fields present an outstanding computational problem due to strongly anisotropic atom-molecule interactions that depend on the relative orientation of the collision partners, as well as on their vibrational degrees of freedom. Here, we present the first numerically exact three-dimensional quantum scattering calculations on strongly anisotropic atom-molecule (Li+CaH) collisions in an external magnetic field based on the parity-adapted total angular momentum representation and a new three-dimensional potential energy surface (PES) for the triplet Li-CaH collision complex using the unrestricted coupled cluster method with single, double and perturbative triple excitations [UCCSD(T)] and a large quadruple-zeta type basis set. We find that while the full three-dimensional treatment is necessary for the accurate description of Li ($M_S=1/2$)+CaH ($v=0,N=0,M_S=1/2$) collisions as a function of magnetic field, the magnetic resonance density and statistical properties of spin-polarized atom-molecule collisions are not strongly affected by vibrational degrees of freedom, justifying the rigid-rotor approximation used in previous calculations. We observe rapid, field-insensitive vibrational quenching in ultracold Li ($M_S=1/2$)+CaH ($v=1,N=0, M_S=1/2$) collisions, leading to efficient collisional cooling of CaH vibrations.
磁场中超冷原子-分子碰撞的全维量子散射计算:分子振动的作用
由于原子-分子间的强各向异性相互作用依赖于碰撞伙伴的相对方向,以及它们的振动自由度,对外部场中超冷分子碰撞的严格量子散射计算提出了一个突出的计算问题。本文基于奇偶自适应的总角动量表示,首次对外磁场中强各向异性原子-分子(Li+CaH)碰撞的三维量子散射进行了精确的数值计算,并利用具有单、双重和摄动三重激励[UCCSD(T)]和一个大的四zeta型基集。我们发现,虽然完整的三维处理对于Li ($M_S=1/2$)+CaH ($v=0,N=0,M_S=1/2$)碰撞作为磁场函数的精确描述是必要的,但自旋极化原子-分子碰撞的磁共振密度和统计性质不受振动自由度的强烈影响,证明了以前计算中使用的刚性转子近似是正确的。在超冷Li ($M_S=1/2$)+CaH ($v=1,N=0, M_S=1/2$)碰撞中,我们观察到快速、场不敏感的振动淬火,导致CaH振动的有效碰撞冷却。
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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