Statistical Assemblies of Particles with Spin

Abstract: Spin, $s$ in quantum theory can assume only half odd integer or integer values. For a given $s$, there exist $n=2s+1$ states $|s,m\rangle$, $m=s,s-1,........,-s$. A statistical assembly of particles (like a beam or target employed in experiments in physics) with the lowest value of spin $s=\frac {1}{2}$ can be described in terms of probabilities $p_m$ assigned to the two states $m=\pm \frac {1}{2}$. A generalization of this concept to higher spins $s>\frac {1}{2}$ leads only to a particularly simple category of statistical assemblies known as Oriented systems'. To provide a comprehensive description of all realizable categories of statistical assemblies in experiments, it is advantageous to employ the generators of the Lie group $SU(n)$. The probability domain then gets identified to the interior of regular polyhedra in $\Re^{n-1},$ where the centre corresponds to an unpolarized assembly and the vertices representpure' states. All the other interior points correspond to mixed' states. The higher spin system has embedded within itself a set of $s(2s+1)$ independent axes, which are determinable empirically. Only when all these axes turn out to be collinear, the simple category ofOriented systems' is realized, where probabilities $p_m$ are assigned to the states $|s,m\rangle$. The simplest case of higher spin $s=1$ provides an illustrative example, where additional features of aligned' and more generalnon oriented' categories are displayed.