Rotational tunneling dynamics of methyl groups measured by spectral hole burning

K. Orth, J. Friedrich
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Abstract

Rotational tunneling of methyl groups has been studied extensively in the past decades [1]. The specific features of the dynamics of rotational tunneling are a consequence of the basic laws of quantum mechanics. The reason is that a 2π3-rotation of a methyl group is equivalent to a two-fold permutation of identical particels. As a consequence, the symmetry of the total wave function of the methyl group has to be invariant with respect to a rotation. This symmetry correlation has a dramatic influence on the relaxation dynamics between different rotational states. To observe a rotational tunneling relaxation an interaction is necessary, which breaks the strict symmetry correlation. For the CH3-methyl group this interaction is the nuclear spin-spin coupling and for the CD3-methyl group it is the nuclear quadrupole interaction of the deuteron with the electric field gradient. The magnitude of this interaction is so small that the respective relaxation times can be as long as months at low temperatures. Because of the influence of the nucleus involved in the rotational tunneling dynamics the relaxation of the rotational states is called nuclear spin conversion. Theoretical models have been published for the protonated [2, 3] as well as for the deuterated methyl group [4]. They basically predict three different kinds of relaxation processes (Direct, Raman and Orbach process) depending on the rotor parameters which are the V3-potential, the tunneling splitting and the phonon coupling. These, in turn depend on isotopic substitution.
用光谱孔燃烧法测量甲基的旋转隧穿动力学
在过去的几十年里,甲基的旋转隧穿得到了广泛的研究[1]。旋转隧穿动力学的具体特征是量子力学基本定律的结果。原因是甲基的2π - 3旋转相当于相同粒子的2倍排列。因此,甲基的总波函数的对称性对于旋转必须是不变的。这种对称性关联对不同旋转态之间的弛豫动力学有显著的影响。为了观察旋转隧穿弛豫,必须有一个相互作用,它打破了严格的对称关联。对于ch3 -甲基,这种相互作用是原子核自旋-自旋耦合,对于cd3 -甲基,它是氘核与电场梯度的核四极相互作用。这种相互作用的幅度是如此之小,以至于在低温下各自的弛豫时间可以长达数月。由于参与旋转隧穿动力学的原子核的影响,转动态的松弛称为核自旋转换。已经发表了质子化[2,3]和氘化甲基[4]的理论模型。他们基本上预测了三种不同的弛豫过程(直接、拉曼和奥巴赫过程),这取决于转子参数,即v3势、隧道分裂和声子耦合。而这又取决于同位素取代。
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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