Author: Siminovitch, David¹

Source: Molecular Physics, Volume 106, Numbers 21-23, November 2008 , pp. 2607-2625(19)

Publisher: Taylor and Francis Ltd

Abstract:

Choosing the rotation angle-rotation axis parameters [image omitted] instead of the conventional Euler angle parameters {α, β, γ} to parametrise rotations, and a spherical tensor operator basis, Happer was the first to propose a novel multipole operator expansion of the rotation operator [image omitted] [W. Happer, Ann. Phys. (N.Y.) 48, 579 (1968)]. As Happer pointed out, such an expansion in irreducible spherical tensor operators readily lends itself to the methods of Racah algebra, a feature we exploit to simplify the calculus of rotation matrix products. Working with a Clebsch-Gordan coefficient expansion [W. Happer, ibid. cit.; M.S. Marinov, Yad. Fiz. 5, 943 (1967)] of the corresponding rotation matrices [image omitted], and closure relations for these (2J + 1)-dimensional irreducible representations of the rotation group, we state, and prove for the first time, simple recoupling coefficient expansions for rotation matrix products. With an eye towards applications in NMR, where multiple rotations in spin or coordinate space often require the efficient evaluation of such rotation matrix products, we focus on expansions defining the matrices representing the result of two or three consecutive rotations. We show that the coefficients of these expansions are defined by 6 - j symbols and bipolar spherical harmonics (two rotations), or by 9 - j symbols and tripolar spherical harmonics (three rotations). We show that these recoupling coefficient expansions, in conjunction with Racah algebra, are the cornerstone of an unusually simple and direct method of (1) proving the Euler-Rodrigues (quaternion) parameter [image omitted] composition rules for two and three consecutive rotations and (2) constructing rotational invariants expressed in Weyl-invariant form. These methods are distinguished by their independence on the usual algebraic approaches, either those of operator algebra, or ordinary algebra.

Keywords: coupling coefficients; rotation matrices; Racah algebra; multipolar harmonics; matrix products

Document Type: Research article

DOI: 10.1080/00268970802623794

Affiliations: 1: Department of Physics, The University of Lethbridge, Alberta, Canada

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