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Universal Alternating Semiregular Polytopes

Part of: Real and complex geometry Polytopes and polyhedra

Published online by Cambridge University Press:  12 February 2020

B. Monson  and
Egon Schulte
B. Monson
Affiliation:
University of New Brunswick, Fredericton, New BrunswickE3B 5A3
Egon Schulte
Affiliation:
Northeastern University, Boston, Massachussetts, 02115, USA
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Abstract

In the classical setting, a convex polytope is said to be semiregular if its facets are regular and its symmetry group is transitive on vertices. This paper continues our study of alternating semiregular abstract polytopes, which have abstract regular facets, still with combinatorial automorphism group transitive on vertices and with two kinds of regular facets occurring in an alternating fashion.

Our main concern here is the universal polytope ${\mathcal{U}}_{{\mathcal{P}},{\mathcal{Q}}}$, an alternating semiregular $(n+1)$-polytope defined for any pair of regular $n$-polytopes ${\mathcal{P}},{\mathcal{Q}}$ with isomorphic facets. After a careful look at the local structure of these objects, we develop the combinatorial machinery needed to explain how ${\mathcal{U}}_{{\mathcal{P}},{\mathcal{Q}}}$ can be constructed by “freely assembling” unlimited copies of ${\mathcal{P}}$, ${\mathcal{Q}}$ along their facets in alternating fashion. We then examine the connection group of ${\mathcal{U}}_{{\mathcal{P}},{\mathcal{Q}}}$, and from that prove that ${\mathcal{U}}_{{\mathcal{P}},{\mathcal{Q}}}$ covers any $(n+1)$-polytope ${\mathcal{B}}$ whose facets alternate in any way between various quotients of ${\mathcal{P}}$ or ${\mathcal{Q}}$.

Keywords

semiregular polytopeabstract polytopegroup amalgamationCoxeter group

MSC classification

Primary: 51M20: Polyhedra and polytopes; regular figures, division of spaces
Secondary: 52B15: Symmetry properties of polytopes
Type
Article
Information
Canadian Journal of Mathematics , Volume 73 , Issue 2 , April 2021 , pp. 572 - 595
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Copyright
© Canadian Mathematical Society 2020

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Footnotes

The second author is supported by the Simons Foundation Award No. 420718.

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