The 20th century saw a succession of generalisations of the idea of a regular polyhedron, leading to several new classes.
Regular skew apeirohedra In the first decades, Coxeter and Petrie allowed "saddle" vertices with alternating ridges and valleys, enabling them to construct three infinite folded surfaces which they called
regular skew polyhedra. Coxeter offered a modified
Schläfli symbol {l,m|n} for these figures, with {l,m} implying the
vertex figure, with
m regular
l-gons around a vertex. The
n defines
n-gonal
holes. Their vertex figures are
regular skew polygons, vertices zig-zagging between two planes.
Regular skew polyhedra Finite regular skew polyhedra exist in 4-space. These finite regular skew polyhedra in 4-space can be seen as a subset of the faces of
uniform 4-polytopes. They have planar
regular polygon faces, but
regular skew polygon vertex figures. Two dual solutions are related to the
5-cell, two dual solutions are related to the
24-cell, and an infinite set of self-dual
duoprisms generate regular skew polyhedra as {4, 4 n}. In the infinite limit these approach a
duocylinder and look like a
torus in their
stereographic projections into 3-space.
Regular polyhedra in non-Euclidean and other spaces Studies of
non-Euclidean (
hyperbolic and
elliptic) and other spaces such as
complex spaces, discovered over the preceding century, led to the discovery of more new polyhedra such as
complex polyhedra which could only take regular geometric form in those spaces.
Regular polyhedra in hyperbolic space , {6,3,3}, has
hexagonal tiling, {6,3}, facets with vertices on a
horosphere. One such facet is shown in as seen in this
Poincaré disk model. In H3
hyperbolic space,
paracompact regular honeycombs have Euclidean tiling
facets and
vertex figures that act like finite polyhedra. Such tilings have an
angle defect that can be closed by bending one way or the other. If the tiling is properly scaled, it will
close as an
asymptotic limit at a single
ideal point. These Euclidean tilings are inscribed in a
horosphere just as polyhedra are inscribed in a sphere (which contains zero ideal points). The sequence extends when hyperbolic tilings are themselves used as facets of noncompact hyperbolic tessellations, as in the
heptagonal tiling honeycomb {7,3,3}; they are inscribed in an equidistant surface (a 2-
hypercycle), which has two ideal points.
Regular tilings of the real projective plane Another group of regular polyhedra comprise tilings of the
real projective plane. These include the
hemi-cube,
hemi-octahedron,
hemi-dodecahedron, and
hemi-icosahedron. They are (globally)
projective polyhedra, and are the projective counterparts of the
Platonic solids. The tetrahedron does not have a projective counterpart as it does not have pairs of parallel faces which can be identified, as the other four Platonic solids do. These occur as dual pairs in the same way as the original Platonic solids do. Their Euler characteristics are all 1.
Abstract regular polyhedra By now, polyhedra were firmly understood as three-dimensional examples of more general
polytopes in any number of dimensions. The second half of the century saw the development of abstract algebraic ideas such as
Polyhedral combinatorics, culminating in the idea of an
abstract polytope as a
partially ordered set (poset) of elements. The elements of an abstract polyhedron are its body (the maximal element), its faces, edges, vertices and the
null polytope or empty set. These abstract elements can be mapped into ordinary space or
realised as geometrical figures. Some abstract polyhedra have well-formed or
faithful realisations, others do not. A
flag is a connected set of elements of each dimension – for a polyhedron that is the body, a face, an edge of the face, a vertex of the edge, and the null polytope. An abstract polytope is said to be
regular if its combinatorial symmetries are transitive on its flags – that is to say, that any flag can be mapped onto any other under a symmetry of the polyhedron. Abstract regular polytopes remain an active area of research. Five such regular abstract polyhedra, which can not be realised faithfully, were identified by
H. S. M. Coxeter in his book
Regular Polytopes (1977) and again by
J. M. Wills in his paper "The combinatorially regular polyhedra of index 2" (1987). All five have C2×S5 symmetry but can only be realised with half the symmetry, that is C2×A5 or icosahedral symmetry. They are all topologically equivalent to
toroids. Their construction, by arranging
n faces around each vertex, can be repeated indefinitely as tilings of the
hyperbolic plane. In the diagrams below, the hyperbolic tiling images have colors corresponding to those of the polyhedra images. :
Petrie dual The
Petrie dual of a regular polyhedron is a
regular map whose vertices and edges correspond to the vertices and edges of the original polyhedron, and whose faces are the set of
skew Petrie polygons.
Spherical polyhedra The usual five regular polyhedra can also be represented as spherical tilings (tilings of the
sphere):
Regular polyhedra that can only exist as spherical polyhedra For a regular polyhedron whose Schläfli symbol is {
m,
n}, the number of polygonal faces may be found by: :N_2=\frac{4n}{2m+2n-mn} The
Platonic solids known to antiquity are the only integer solutions for
m ≥ 3 and
n ≥ 3. The restriction
m ≥ 3 enforces that the polygonal faces must have at least three sides. When considering polyhedra as a
spherical tiling, this restriction may be relaxed, since
digons (2-gons) can be represented as spherical lunes, having non-zero
area. Allowing
m = 2 admits a new infinite class of regular polyhedra, which are the
hosohedra. On a spherical surface, the regular polyhedron {2,
n} is represented as
n abutting lunes, with interior angles of 2/
n. All these lunes share two common vertices. A regular
dihedron, {
n, 2} (2-hedron) in three-dimensional
Euclidean space can be considered a
degenerate prism consisting of two (planar)
n-sided
polygons connected "back-to-back", so that the resulting object has no depth, analogously to how a digon can be constructed with two
line segments. However, as a
spherical tiling, a dihedron can exist as nondegenerate form, with two
n-sided faces covering the sphere, each face being a
hemisphere, and vertices around a
great circle. It is
regular if the vertices are equally spaced. The hosohedron {2,
n} is dual to the dihedron {
n,2}. Note that when
n = 2, we obtain the polyhedron {2,2}, which is both a hosohedron and a dihedron. All of these have Euler characteristic 2. == See also ==