The shape of the
world.
(Appendix 2) The five Pythagorean solids.
A “platonic solid” is a convex regular
polyhedron (Figure 1). This means that their faces are equal regular polygons
and that in all the vertices the number of incident faces is the same. In
addition, the well-known Euler's formula is fulfilled:
V – A + C = 2, (Equation
1)
where V is the number of vertices, A the
number of edges and C the number of faces.
Fig. 1. The Platonic
solids
(Credit:
Максим Пе
[CC BY-SA 4.0] https://commons.wikimedia.org/wiki/File:Platonic_solids.jpg)
In three of the solids the faces are
equilateral triangles:
- the tetrahedron: V = 4, A = 6, C = 4,
- the octahedron: V = 6, A = 12, C = 8,
- the icosahedron: V = 12, A = 30,
C = 20;
in the cube or hexahedron, the
faces are squares, V = 8, A = 12, C = 6; and in the dodecahedron the
faces are regular pentagons, V = 20, A = 30,
C = 12
These solids, which
Sagan calls "Pythagoreans", have been known for thousands of years.
For Plato (427 BC-347 BC) they represented the elemental components of the
world, respectively: fire, air, water, earth and the shape of the universe.
The amazing beauty of
these bodies lies in their mirror and rotational symmetry, which has attracted
the interest of many artists throughout history. Their forms also appear in
Nature: there are minerals that crystallize in the form of a polyhedron, such as
the pyrite in Figure 2, and it is possible that the observation of these
crystals is at the origin of Plato's ideas. They also appear in the arrangement
of the atoms of certain molecules [1], in the skeletons of radiolaria
[2] and in the capsid of some viruses [3].
Fig. 2. Pyrite crystal
(Credit: Rob Lavinsky,
iRocks.com [CC-BY-SA-3.0]
https://commons.wikimedia.org/wiki/File:Pyrite-135018.jpg)
There are only five
platonic solids. A proof already appears in the Elements of Euclid (325
BC-265 BC). Here, instead of the algebraic proof that was given in Sagan's
original book, we will do another one, based on the fact that, at each vertex,
the sum of the interior angles of the incident faces must be less than 360º.
On a regular n-sided
polygon, each interior angle measures
a = 180 º - 360º/n,
in a polyhedron, if r is the number of edges
(and also faces) that affect a vertex, we have
r • a < 360º,
as we can see if we imagine that we squash the vertex and open the faces
until we put them on the same plane. Since n cannot be less than 3, we see that
- for n = 3 we have r • 60 < 360, so
r = 3,4,5;
- for n = 4 we have r • 90 < 360, so
r = 3;
- for n = 5 we have r • 108 < 360,
hence r = 3,
- for a higher n, no r is valid, since r
cannot be less than 3.
On the other hand,
since each edge is bordered by two faces, when counting the number of edges we
will have n • C = 2A; and since each edge has two vertices, we shall have r • V
= 2A. If we use these formulas, Equation 1 becomes
1/r + 1/n = 1/A + 1/2,
which gives us, in each case, the correct
value of A, and from there those of V and C. With this we have proven that
there are no more regular polyhedra.
In mathematics, these
polyhedra are related to group theory, due to their symmetries; with graph
theory, since a graph is obtained by projecting its edges onto the plane of one
of its faces; and, above all, with Topology, since the deep understanding of Equation
1 led Poincaré (1854-1912) to boost this new specialty, when he introduced the notions of homotopy and homology.
Equation 1 is also true for semi-regular polyhedra, for example platonic
solids with truncated corners (Figure 4), already studied by Archimedes (287
BC-212 BC); and for prisms and antiprisms, where faces are
regular polygons, but of two different types.
It is also true for
some regular non-convex polyhedra, such as the starry polyhedron, in
Figure 3, which is an illustration by Leonardo da Vinci (1452-1519) for the
book Divina proportione, by Luca Pacioli (1445–1517). This polyhedron is
a "stellation" of the icosidodecahedron and has V = 62, A =
180, and C = 120 triangles.
Fig. 3. Starry polyhedron
(Credit: Leonardo da Vinci
[Public domain]
https://commons.wikimedia.org/wiki/File:De_divina_proportione_-_Dodecaedron_Abscisum_Elevatum_Solidum.jpg)
From the topological
point of view, the essential thing of a polyhedron is that its faces form a
closed, that is, limited and borderless, surface. The edges are thus lines
drawn on the surface, which intersect at the vertices. On the right side of
Figure 4 it is clear that a polyhedron is essentially a sphere, with some
decomposition of its surface into regions. As we will see below, this idea is
crucial for the proof of Equation 1.
Fig. 4. Truncated
icosahedron
(Credit: Aaron Rotenberg [CC
BY-SA 4.0]
https://commons.wikimedia.org/wiki/File:Comparison_of_truncated_icosahedron_and_soccer_ball.png)
This equation, stated
by Euler (1707-1783) [4], has many different proofs. Coxeter (1907-2003) gave
in [5] the following one: we go over the edges of the polyhedron so that we
pass only once through each of the V vertices. In this way we will have a
“tree” that has V - 1 branches, which are the traversed edges (in Figure 5 some
edges are repeated). Each missing edge in the tree limits two faces and
therefore we can draw a path that connects the C centers of the faces. This
path is connected, that is, it can be reached from one face to any other, since
otherwise there would be two faces separated by a closed circuit of the tree,
but by definition a tree has no circuits.
On the other hand, our
path cannot have circuits either, since it would separate the surface into
two parts, with some vertices of the first tree in each one, which can not
be true. Thus, the second path is also a tree, and has C - 1 branches. Now,
each edge of the polyhedron is a branch of one of the two trees, so
(V - 1) + (C - 1) = A,
which is Euler's formula.
Fig. 5. Proof of Euler's
formula
(Credit: Pixelmaniac pictures (Leave a reply) [Public
domain] and own elaboration.
https://upload.wikimedia.org/wikipedia/commons/c/ce/Foldable_tetrahedron_%28blank%29.svg)
The essential property
used in the previous proof, highlighted by Poincaré [6], is that in a sphere
and therefore in all the polyhedra we are considering, any simple closed curve
drawn in it will disconnect it. The sphere is said to be "simply
connected," or, what is the same, to have "gender zero." Said more
loosely, the sphere has no "handles."
In contrast, a torus
(Figure 6) has a handle, that is, its gender is g = 1. For a polyhedron drawn
on a surface of gender g, the "Euler-Poincaré formula" will give us
V – A + C = 2 - 2g.
Fig. 6. Toroidal
polyhedron.
(Credit: Dr. Ozan Yarman [CC BY-NC-SA 3.0] https://www.nodebox.net/code/index.php/Mark_Meyer_%7c_Parametric_surfaces_%7c_torus)
These ideas led, at
the beginning of the 20th century, to the classification of all surfaces, and
more recently to the generalization, by Perelman (1966-), of this
classification to other dimensions [7].
In Carl Sagan's
original Cosmos, Platonic solids appear twice: when he recounts the
ancient Greeks' ideas about the elements; and when he comments on Kepler's
theory (1571-1630) on the orbits of the planets. The merit of these
speculations was to establish the principle that it is possible to explain the
universe through mathematical models. Centuries later, the objective of
Mathematics continues to be to imagine, from geometric and topological methods
such as those we have seen, all possible theoretical worlds and then discard
those that do not conform to the laws of astrophysics.
References:
[1] S. Álvarez , Polyhedra
in (inorganic) chemistry, Dalton Trans. 2209-2233
(2005), https://www.doi.org/10.1039/b503582c
[2] M. Mallo Zurdo, Sistemas radiolarios.
Geometrías y arquitecturas derivadas. Tesis doctoral. Universidad
Politécnica de Madrid, 2015.
[4] L. Euler, Elementa doctrinae solidorum,
Euler Archive – Obras completas. E230 (1758). https://scholarlycommons.pacific.edu/euler-works/230
[5] H.S.M. Coxeter, Regular
polytopes. Methuen & Co. Ltd. London, 1948.
[6] H. Poincaré, Sur
la généralisation d’un théorème d’Euler relatif aux polyèdres. Comptes Rendus Acad. Sci., t. 117,
p. 144-145 (17 juillet 1893). http://analysis-situs.math.cnrs.fr/
[7] Virtual and
manipulative geometrical and topological games, Juegos Topológicos del Mago
Moebius. https://topologia.wordpress.com/2009/03/04/la-conjetura-de-poincare/
Bibliography:
(1) Henar Lanza González. Matemática y
física en el Timeo de Platón. Poliedros regulares y elementos naturales. Praxis
Filosófica Nueva serie, No. 40, enero-junio 2015: 85 – 112.
(2) Marjorie Senechal
Editor. Shaping Space: Exploring Polyhedra in Nature, Art, and the
Geometrical Imagination. Springer, 2013.
(3) J. R. Weeks. The shape of space, Second Edition, Marcel
Dekker, 2002.
(4) E. Cabezas Rivas y V. Miquel Molina.
Demostración de Hamilton-Perelman de las conjeturas de Poincaré y
Thurston, La Gaceta de la RSME, Vol. 9.1 (2006), 15–42.
Enrique Macías
Virgós.
Ph.D. Mathematics.
Professor of Geometry
and Topology.
Departament of Mathematics,University of
Santiago de Compostela.
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