Integral Planes and Unit-Norm Polytopes

Abstract

We introduce and study integral planes associated with crystallographic and non-crystallographic integral systems in real composition algebras. For an integral order in such an algebra we define the plane 2 with quadratic form Q(x,y)=(x)+(y), the axis shell, the balanced shell, and the corresponding unit-normalised spherical polytopes. For ten crystallographic orders we recover, in one uniform construction, the orthogonal-direct-sum root systems 2A1, A2 A2, 4A1, D4 D4, 16A1, and E8 E8 (with classical-polytope realisations including the square, the 16-cell, the 24-cell, and the Gosset polytope 421); for two non-crystallographic orders we obtain H2 H2 (decagonal tegum) and H4 H4 (600-cell tegum) over []. We prove a rank-obstruction theorem that closes, unconditionally and by a purely Coxeter-theoretic argument, the existence question for an indecomposable rank-eight golden octonion order: no such order can exist. On the balanced shell side, we identify the genuine algebraic Hopf map A(a,b)=(2a b,(a)-(b)) and prove that its restriction to the balanced shell is a finite principal fibration of the unit loop, valid both for the associative case and for the alternative Moufang case.