The Leech lattice occupies a central place in exceptional mathematics and coding theory, but because it is 24-dimensional, its geometric structure is difficult to visualize. We elucidate a coordinate system employed in Conway’s and Sloane’s iSphere Packings, Lattices and Groups/i to describe and to illustrate the environs of the Leech lattice’s deep holes but never explained in that book. By using this coordinate system for the deep holes, we are able to provide colorful diagrams for the environs of several deep holes. The most interesting of those deep holes is IE/Isub8/subsup3/sup, and we describe a newi E/isub8/subsup3 /sup-based coordinate system for the Leech lattice. We enumerate the Delaunay cells of the Leech lattice immediately neighboring a Delaunay cell of typei E/isub8/subsup3/sup, neighboring in the sense of intersecting the latter cell in a 23-dimensional face. There are 729 such faces, but fewer isometry classes of neighboring cells, including both deep holes and shallow holes. We also enumerate the Delaunay cells of the Leech lattice in close proximity to a Delaunay cell of typei E/isub8/subsup3/sup, close in the sense of having all vertices less than i√2.2/i distant from the center ofi E/isub8/subsup3/sup; the latter’s circumradius is √2. Neither of the two classes of Delaunay cells enumerated below is a subset of the other. We next consider conjectures about the Leech lattice and the several lattices with similar properties, most especially the lattices i /i, Asub2/sub, i /isup2/sup, Dsub4/sub, and Esub8/sub. Other lattices sharing fewer optimality properties include the Coxeter-Todd lattice Ksub12/sub and the Barnes-Wall lattice Λsub16/sub. The properties of greatest interest are those involving various measures of high degrees of symmetry, as well as various measures of high efficiency in packing and covering. Our culminating theorem is a partial classification of lattices that have very strong properties similar to those of the Leech lattice.
Hal M. Switkay (Mon,) studied this question.