Hendecahedron

A hendecahedron (or undecahedron) is a polyhedron with 11 faces. There are numerous topologically distinct forms of a hendecahedron, for example the decagonal pyramid, and enneagonal prism.

The bisymmetric hendecahedron contains 11 faces and can be arranged in 3D without gaps.

Three forms are Johnson solids: augmented hexagonal prism, biaugmented triangular prism, and elongated pentagonal pyramid.

Two classes, the bisymmetric and the sphenoid hendecahedra, are space-filling.[1]

Name of hendecahedron

The name of hendecahedron is based on its meaning. Hen- represents one. Deca represents ten, and when combined with the polyhedron suffix -hedron, the name becomes Hendecahedron.

Common Hendecahedron

In all the convex hendecahedrons, there are a total of 440,564 convex ones with distinct differences in topology. There are significant differences in the structure of topology, which means two types of polyhedrons cannot be transformed by moving vertex positions, twisting, or scaling, such as a pentagonal pyramid and a nine diagonal column. They can't change with each other, so their topology structure is different. But the pentagonal prism and enneagonal prism can interchange by stretching out or drawing back one of the nine sides of the scale, so the triangulum prism and the triangulum pyramid have no obvious difference in topology.

The common hendecahedrons are cones, cylinders, some Jason polyhedrons, and the semi-regular polyhedron. The semi-regular polyhedron here is not the Archimedean solid, but the enneagonal prism.

Other hendecahedrons include enneagonal prism, Spherical octagonal pyramid, two side taper triangular prism of the duality of six, side cone Angle and bisymmetric hendecahedron, which can close shop space.

Bisymmetric Hendecahedron

The Bisymmetric Hendecahedron is a space-filling polyhedron which can be assembled into layers of interpenetrating "boat-shaped" tetramers, which in turn are then stacked to fill space; it is hence a three-dimensional analogue of the Cairo pentagon.

Net of Bisymmetric Hendecahedron

Sphenoid Hendecahedron

The Sphenoid Hendecahedron is a space-filling polyhedron which can be assembled into layers of the Floret tiling, which in turn are stacked to fill space.

Hendecahedron in Chemistry

In the chemistry, after removing all 18 sides in borane hydrogen ions ([B11H11]), it is an Octadecahedron. If making a perpendicular to the center of gravity to the surface of a boron atom, a new polyhedron is constructed, which is 18 surface structures of the dual polyhedron, also one of hendecahedrons.

Convex

There are 440,564 topologically distinct convex hendecahedra, excluding mirror images, having at least 8 vertices.[2] (Two polyhedra are "topologically distinct" if they have intrinsically different arrangements of faces and vertices, such that it is impossible to distort one into the other simply by changing the lengths of edges or the angles between edges or faces.)

gollark: It takes up 80GB of space on my server.
gollark: Yep!
gollark: Hmm, 6 million actually.
gollark: (* in the styropyro server, excluding what I am sure is a lot of weird disused hidden ones)
gollark: You could even run 50 copies of yourself in parallel and monitor all channels ever!

References

  1. Inchbald (1996)
  2. Counting polyhedra
  • Thomas H. Sidebotham. The A to Z of Mathematics: A Basic Guide. John Wiley & Sons. 2003: 237. ISBN 9780471461630
  • Steven Dutch: How Many Polyhedra are There? (http://www.uwgb.edu/dutchs/symmetry/POLYHOW M.HTM)
  • Counting polyhedra (http://www.numericana.com/data/polycount.htm) numericana.com [2016-1-10]
  • Inchbald, Guy. "Five Space-Filling Polyhedra." The Mathematical Gazette 80, no. 489 (November 1996): 466-475
  • Space-Filling Bisymmetric Hendecahedron. [2013-04-11]
  • Anderson, Ian. "Constructing Tournament Designs." The Mathematical Gazette 73, no. 466 (December 1989): 284-292
  • Holleman, A. F.; Wiberg, E., Inorganic Chemistry, San Diego: Academic Press: 1165, 2001, ISBN 0-12-352651-5
  • Inchbald, Guy (1996). "Five space-filling polyhedra". The Mathematical Gazette. 80 (489): 466–475. doi:10.2307/3618509. ISSN 0025-5572. Zbl 0885.52011.
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