Group-theoretical classification of orientable objects and particle phenomenology
Abstract
In our previous works, we have proposed a quantum description of relativistic orientable objects by a scalar field on the Poincar\'e group. This description is, in a sense, a generalization of ideas used by Wigner, Casimir and Eckart back in the 1930's in constructing a non-relativistic theory of a rigid rotator. The present work is a continuation and development of the above mentioned our works. The position of the relativistic orientable object in Minkowski space is completely determined by the position of a body-fixed reference frame with respect to the space-fixed reference frame, and can be specified by elements q of the motion group of the Minkowski space - the Poincar\'e group M(3,1). Quantum states of relativistic orientable objects are described by scalar wave functions f(q) where the arguments q=(x,z) consist of Minkowski space-time points x, and of orientation variables z given by elements of the matrix Z∈ SL(2,C). Technically, we introduce and study the so-called double-sided representation T(g)f(q)=f(gl-1qgr), g=(gl,gr)∈ M, of the group M, in the space of the scalar functions f(q). Here the left multiplication by gl-1 corresponds to a change of space-fixed reference frame, whereas the right multiplication by gr corresponds to a change of body-fixed reference frame. On this basis, we develop a classification of the orientable objects and draw the attention to a possibility of connecting these results with the particle phenomenology. In particular, we demonstrate how one may identify fields described by linear and quadratic functions of z with known elementary particles of spins 0,12, and 1. The developed classification does not contradict the phenomenology of elementary particles and, moreover, in some cases give its group-theoretic explanation.
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