DOCSLIB.ORG

Chains of Antiprisms

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Chains of Antiprisms Chains of antiprisms Citation for published version (APA): Verhoeff, T., & Stoel, M. (2015). Chains of antiprisms. In Bridges Baltimore 2015 : Mathematics, Music, Art, Architecture, Culture, Baltimore, MD, USA, July 29 - August 1, 2015 (pp. 347-350). The Bridges Organization. Document status and date: Published: 01/01/2015 Document Version: Publisher’s PDF, also known as Version of Record (includes final page, issue and volume numbers) Please check the document version of this publication: • A submitted manuscript is the version of the article upon submission and before peer-review. There can be important differences between the submitted version and the official published version of record. People interested in the research are advised to contact the author for the final version of the publication, or visit the DOI to the publisher's website. • The final author version and the galley proof are versions of the publication after peer review. • The final published version features the final layout of the paper including the volume, issue and page numbers. Link to publication General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal. If the publication is distributed under the terms of Article 25fa of the Dutch Copyright Act, indicated by the “Taverne” license above, please follow below link for the End User Agreement: www.tue.nl/taverne Take down policy If you believe that this document breaches copyright please contact us at: [email protected] providing details and we will investigate your claim. Download date: 30. Sep. 2021 Proceedings of Bridges 2015: Mathematics, Music, Art, Architecture, Culture Chains of Antiprisms Tom Verhoeff ∗ Melle Stoel Department of Mathematics and Computer Science Da Costastraat 18 Eindhoven University of Technology 1053 ZC Amsterdam P.O. Box 513 Netherlands 5600 MB Eindhoven, Netherlands [email protected] [email protected] Abstract We prove a property of antiprism chains and show some artwork based on this property. Introduction The sculpture Corkscrew was featured at the Bridges 2014 Art Exhibition [1]. It is constructed from an- tiprisms [4] on regular pentagons, which are either stacked together on their pentagonal faces, or connected on their triangular faces to form zigzag chains. In particular, notice the isosceles ‘triangles’1 consisting of a stack of six antiprisms and two zigzag chains of seven antiprisms. Figure 1 : Sculpture Corkscrew designed and realized by Melle Stoel, constructed from pentago- nal antiprisms At the time when Corkscrew was designed [2], it was only a conjecture that this ‘triangle’ is mathemat- ically precise, that is, that it does not involve any twisting or bending. We will prove the following more general theorem. Consider the antiprism on a regular n-gon, for odd n at least 3. It consists of two regular n-gons connected into a polyhedron by 2n equilateral triangles (see Fig. 2, left). These antiprisms can be connected via diagonally opposite triangles into a zigzag chain, and can be stacked via the n-gons into a tower (see Fig. 2, right). 1There is also a stack of two antiprisms; so, it is more a trapezoid with one quite short edge. 347 Verhoeff and Stoel Figure 2 : Pentagonal antiprism (left); zigzag chain and stack of antiprisms (right) Theorem For every odd n ≥ 3, the diagonal chain of seven such antiprisms is exactly as high as a stack of three antiprisms. Proof Consider a regular n-gon with side length 1. Let R and r be the radii of the circumscribed and inscribed circles (see Fig. 3, left). We then have R sin(π=n) = 1=2. Furthermore, R2 = r2 + 1=4 (Pythagoras applied to triangle R; r; 1=2). Or, R2 − r2 = 1=4. Thus (R − r)(R + r) = 1=4. D Q C R F O r O G A P E B Figure 3 : Top view (left) and side view (right) of odd antiprism In the sidep view (Fig. 3, right), we see a parallelogram ABCD, for which the slanted right edge BC 1 has length 2 3 (the height of an equilateral triangle of side length 1). Its square equals 3=4. The length of the other (horizontal) edge AB equals R + r, since jPAj = r and jPBj = R. Note that jEBj = R − r. Thus, the height h = jECj of the parallelogram satisfies h2 + (R − r)2 = 3=4. 348 Chains of Antiprisms Triangles EBC and F GO are similar (OF is perpendicular to BC; and OG is perpendicular to PQ and to EC). Thus, the lengths of the sides are proportional, that is, for the ratios we have EB : FG = EC : FO = BC : OG. We now know 1p BC = 3 2 OG = (R + r)=2 EB = R − r and so FG = EB · OG=BC p = (R − r)(R + r)= 3 p = 1=(4 3) p = 3=12 = BC=6 From this we find that F is the centroid of the triangular face, and lies at 2=3 of the height; that is, 1=6 of the height higher than the centroid of the antiprism. Figure 4 : Side view of odd antiprism chain, showing how each antiprism center rises one-third of the height Because OF is perpendicular to BC, the line OF (when extended) will pass through the centroid of the next (tilted) antiprism in the chain, and from there through the centroid of the third (again horizontal) antiprism. The centroids of consecutive antiprisms in the chain step up 1=3 of the antiprism’s height. A zigzag chain of seven antiprisms rises six times 1=3 the height, or exactly as much as two antiprisms. Figure 5 : Chain of pentagonal antiprisms rotated along the center line 349 Verhoeff and Stoel Corollary The line through the centroids of the antiprisms in the zigzag chain passes through the centroids of the connecting triangles, intersecting them at a right angle. Consequently, each antiprism in the chain can be rotated over a multiple of 120◦ along that center line, without disturbing the structure. Figure 5 illustrates this. The triangular antiprism equals the octahedron, which is more symmetric than n-gon antiprisms with n > 3. Hence, the rotation of the octahedron in such chains has no visible effect. This rotational freedom is exploited in the sculpture Nonagonal antiprism/Hexagonal tesselation, shown in Figure 6. Here, the straight chains of seven nonagonal antiprisms are bent at every second (i.e., horizontal) antiprism into a triangular shape (three antiprisms to one side), such that the first and the last horizontal antiprism end up above each other, with just room for one antiprism in between them. The connecting non-horizontal antiprisms have been rotated. Figure 6 : Nonagonal antiprism/Hexagonal tesselation, by Melle Stoel Related Work In [3], Stewart studied various loops of polyhedra attached face to face. We do not know whether this includes loops of antiprisms. References [1] Melle Stoel. Corkscrew. Bridges 2014 Art Exhibition. http://gallery.bridgesmathart.org/ exhibitions/2014-bridges-conference/mellestoel (accessed 15 Mar 2015). [2] Melle Stoel. Closed Loops of Antiprisms. Proceedings of Bridges 2014: Mathematics, Music, Art, Ar- chitecture, Culture, pp.285–292. [3] B. M. Stewart. Adventures Among the Toroids: A Study of Quasi-Convex, Aplanar, Tunneled Orientable Polyhedra of Positive Genus Having Regular Faces With Disjoint Interiors (2nd Ed.). Self-published, 1980. [4] Wikipedia contributors. Antiprism— Wikipedia, The Free Encyclopedia. https://en.wikipedia. org/wiki/Antiprism (accessed 15 Mar 2015). 350.
Load more

Recommended publications
  • The Volumes of a Compact Hyperbolic Antiprism
    The volumes of a compact hyperbolic antiprism Vuong Huu Bao joint work with Nikolay Abrosimov Novosibirsk State University G2R2 August 6-18, Novosibirsk, 2018 Vuong Huu Bao (NSU) The volumes of a compact hyperbolic antiprism Aug. 6-18,2018 1/14 Introduction Calculating volumes of polyhedra is a classical problem, that has been well known since Euclid and remains relevant nowadays. This is partly due to the fact that the volume of a fundamental polyhedron is one of the main geometrical invariants for a 3-dimensional manifold. Every 3-manifold can be presented by a fundamental polyhedron. That means we can pair-wise identify the faces of some polyhedron to obtain a 3-manifold. Thus the volume of 3-manifold is the volume of prescribed fundamental polyhedron. Theorem (Thurston, Jørgensen) The volumes of hyperbolic 3-dimensional hyperbolic manifolds form a closed non-discrete set on the real line. This set is well ordered. There are only finitely many manifolds with a given volume. Vuong Huu Bao (NSU) The volumes of a compact hyperbolic antiprism Aug. 6-18,2018 2/14 Introduction 1835, Lobachevsky and 1982, Milnor computed the volume of an ideal hyperbolic tetrahedron in terms of Lobachevsky function. 1993, Vinberg computed the volume of hyperbolic tetrahedron with at least one vertex at infinity. 1907, Gaetano Sforza; 1999, Yano, Cho ; 2005 Murakami; 2005 Derevnin, Mednykh gave different formulae for general hyperbolic tetrahedron. 2009, N. Abrosimov, M. Godoy and A. Mednykh found the volumes of spherical octahedron with mmm or 2 m-symmetry. | 2013, N. Abrosimov and G. Baigonakova, found the volume of hyperbolic octahedron with mmm-symmetry.
    [Show full text]
  • Uniform Polychora
    BRIDGES Mathematical Connections in Art, Music, and Science Uniform Polychora Jonathan Bowers 11448 Lori Ln Tyler, TX 75709 E-mail: [email protected] Abstract Like polyhedra, polychora are beautiful aesthetic structures - with one difference - polychora are four dimensional. Although they are beyond human comprehension to visualize, one can look at various projections or cross sections which are three dimensional and usually very intricate, these make outstanding pieces of art both in model form or in computer graphics. Polygons and polyhedra have been known since ancient times, but little study has gone into the next dimension - until recently. Definitions A polychoron is basically a four dimensional "polyhedron" in the same since that a polyhedron is a three dimensional "polygon". To be more precise - a polychoron is a 4-dimensional "solid" bounded by cells with the following criteria: 1) each cell is adjacent to only one other cell for each face, 2) no subset of cells fits criteria 1, 3) no two adjacent cells are corealmic. If criteria 1 fails, then the figure is degenerate. The word "polychoron" was invented by George Olshevsky with the following construction: poly = many and choron = rooms or cells. A polytope (polyhedron, polychoron, etc.) is uniform if it is vertex transitive and it's facets are uniform (a uniform polygon is a regular polygon). Degenerate figures can also be uniform under the same conditions. A vertex figure is the figure representing the shape and "solid" angle of the vertices, ex: the vertex figure of a cube is a triangle with edge length of the square root of 2.
    [Show full text]
  • The View from Six Dimensions
    Walls and Bridges The view from Six Dimensiosn Wendy Y. Krieger [email protected] ∗ January, Abstract Walls divide, bridges unite. This idea is applied to devising a vocabulary suited for the study of higher dimensions. Points are connected, solids divided. In higher dimensions, there are many more products and concepts visible. The four polytope products (prism, tegum, pyramid and comb), lacing and semiate figures, laminates are all discussed. Many of these become distinct in four to six dimensions. Walls and Bridges Consider a knife. Its main action is to divide solids into pieces. This is done by a sweeping action, although the presence of solid materials might make the sweep a little less graceful. What might a knife look like in four dimensions. A knife would sweep a three-dimensional space, and thus the blade is two-dimensional. The purpose of the knife is to divide, and therefore its dimension is fixed by what it divides. Walls divide, bridges unite. When things are thought about in the higher dimensions, the dividing or uniting nature of it is more important than its innate dimensionality. A six-dimensional blade has four dimensions, since its sweep must make five dimensions. There are many idioms that suggest the role of an edge or line is to divide. This most often hap pens when the referent dimension is the two-dimensional ground, but the edge of a knife makes for a three-dimensional referent. A line in the sand, a deadline, and to the edge, all suggest boundaries of two-dimensional areas, where the line or edge divides.
    [Show full text]
  • Systematics of Atomic Orbital Hybridization of Coordination Polyhedra: Role of F Orbitals
    molecules Article Systematics of Atomic Orbital Hybridization of Coordination Polyhedra: Role of f Orbitals R. Bruce King Department of Chemistry, University of Georgia, Athens, GA 30602, USA; [email protected] Academic Editor: Vito Lippolis Received: 4 June 2020; Accepted: 29 June 2020; Published: 8 July 2020 Abstract: The combination of atomic orbitals to form hybrid orbitals of special symmetries can be related to the individual orbital polynomials. Using this approach, 8-orbital cubic hybridization can be shown to be sp3d3f requiring an f orbital, and 12-orbital hexagonal prismatic hybridization can be shown to be sp3d5f2g requiring a g orbital. The twists to convert a cube to a square antiprism and a hexagonal prism to a hexagonal antiprism eliminate the need for the highest nodality orbitals in the resulting hybrids. A trigonal twist of an Oh octahedron into a D3h trigonal prism can involve a gradual change of the pair of d orbitals in the corresponding sp3d2 hybrids. A similar trigonal twist of an Oh cuboctahedron into a D3h anticuboctahedron can likewise involve a gradual change in the three f orbitals in the corresponding sp3d5f3 hybrids. Keywords: coordination polyhedra; hybridization; atomic orbitals; f-block elements 1. Introduction In a series of papers in the 1990s, the author focused on the most favorable coordination polyhedra for sp3dn hybrids, such as those found in transition metal complexes. Such studies included an investigation of distortions from ideal symmetries in relatively symmetrical systems with molecular orbital degeneracies [1] In the ensuing quarter century, interest in actinide chemistry has generated an increasing interest in the involvement of f orbitals in coordination chemistry [2–7].
    [Show full text]
  • Hwsolns5scan.Pdf
    Math 462: Homework 5 Paul Hacking 3/27/10 (1) One way to describe a polyhedron is by cutting along some of the edges and folding it flat in the plane. The diagram obtained in this way is called a net. For example here is a net for the cube: Draw nets for the tetrahedron, octahedron, and dodecahedron. +~tfl\ h~~1l1/\ \(j [ NJte: T~ i) Mq~ u,,,,, cMi (O/r.(J 1 (2) Another way to describe a polyhedron is as follows: imagine that the faces of the polyhedron arc made of glass, look through one of the faces and draw the image you see of the remaining faces of the polyhedron. This image is called a Schlegel diagram. For example here is a Schlegel diagram for the octahedron. Note that the face you are looking through is not. drawn, hut the boundary of that face corresponds to the boundary of the diagram. Now draw a Schlegel diagram for the dodecahedron. (:~) (a) A pyramid is a polyhedron obtained from a. polygon with Rome number n of sides by joining every vertex of the polygon to a point lying above the plane of the polygon. The polygon is called the base of the pyramid and the additional vertex is called the apex, For example the Egyptian pyramids have base a square (so n = 4) and the tetrahedron is a pyramid with base an equilateral 2 I triangle (so n = 3). Compute the number of vertices, edges; and faces of a pyramid with base a polygon with n Rides. (b) A prism is a polyhedron obtained from a polygon (called the base of the prism) as follows: translate the polygon some distance in the direction normal to the plane of the polygon, and join the vertices of the original polygon to the corresponding vertices of the translated polygon.
    [Show full text]
  • Hexagonal Antiprism Tetragonal Bipyramid Dodecahedron
    Call List hexagonal antiprism tetragonal bipyramid dodecahedron hemisphere icosahedron cube triangular bipyramid sphere octahedron cone triangular prism pentagonal bipyramid torus cylinder square­based pyramid octagonal prism cuboid hexagonal prism pentagonal prism tetrahedron cube octahedron square antiprism ellipsoid pentagonal antiprism spheroid Created using www.BingoCardPrinter.com B I N G O hexagonal triangular square­based tetrahedron antiprism cube prism pyramid tetragonal triangular pentagonal octagonal cube bipyramid bipyramid bipyramid prism octahedron Free square dodecahedron sphere Space cuboid antiprism hexagonal hemisphere octahedron torus prism ellipsoid pentagonal pentagonal icosahedron cone cylinder prism antiprism Created using www.BingoCardPrinter.com B I N G O triangular pentagonal triangular hemisphere cube prism antiprism bipyramid pentagonal hexagonal tetragonal torus bipyramid prism bipyramid cone square Free hexagonal octagonal tetrahedron antiprism Space antiprism prism square­based dodecahedron ellipsoid cylinder octahedron pyramid pentagonal icosahedron sphere prism cuboid spheroid Created using www.BingoCardPrinter.com B I N G O cube hexagonal triangular icosahedron octahedron prism torus prism octagonal square dodecahedron hemisphere spheroid prism antiprism Free pentagonal octahedron square­based pyramid Space cube antiprism hexagonal pentagonal triangular cone antiprism cuboid bipyramid bipyramid tetragonal cylinder tetrahedron ellipsoid bipyramid sphere Created using www.BingoCardPrinter.com B I N G O
    [Show full text]
  • A Fast and Robust Coordination Environment Identification Tool
    doi.org/10.26434/chemrxiv.11294480.v1 ChemEnv : A Fast and Robust Coordination Environment Identification Tool David Waroquiers, Janine George, Matthew Horton, Stephan Schenk, Kristin Persson, Gian-Marco Rignanese, Xavier Gonze, Geoffroy Hautier Submitted date: 28/11/2019 • Posted date: 17/12/2019 Licence: CC BY-NC-ND 4.0 Citation information: Waroquiers, David; George, Janine; Horton, Matthew; Schenk, Stephan; Persson, Kristin; Rignanese, Gian-Marco; et al. (2019): ChemEnv : A Fast and Robust Coordination Environment Identification Tool. ChemRxiv. Preprint. https://doi.org/10.26434/chemrxiv.11294480.v1 Coordination or local environments have been used to describe, analyze, and understand crystal structures for more than a century. Here, we present a new tool called ChemEnv, which can identify coordination environments in a fast and robust manner. In contrast to previous tools, the assessment of the coordination environments is not biased by small distortions of the crystal structure. Its robust and fast implementation enables the analysis of large databases of structures. The code is available open source within the pymatgen package and the software can as well be used through a web app available on http://crystaltoolkit.org through the Materials Project. File list (2) paper.pdf (4.27 MiB) view on ChemRxiv download file supplementary_information.pdf (159.36 KiB) view on ChemRxiv download file 1 ChemEnv : A fast and robust coordination environment identification tool David Waroquiers,a Janine George,a Matthew Horton,b;c Stephan Schenk,d Kristin A. Persson,b;c Gian-Marco Rignanese,a Xavier Gonzea;e and Geoffroy Hautier a* aInstitute of Condensed Matter and Nanosciences, Universit´ecatholique de Louvain, Chemin des Etoiles´ 8, 1348 Louvain-la-Neuve, Belgium, bEnergy Technologies Area, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA, cDepartment of Materials Science and Engineering, University of California, Berkeley, CA 94720, USA, dBASF SE, Digitalization of R&D, Carl-Bosch-Str.
    [Show full text]
  • [ENTRY POLYHEDRA] Authors: Oliver Knill: December 2000 Source: Translated Into This Format from Data Given In
    ENTRY POLYHEDRA [ENTRY POLYHEDRA] Authors: Oliver Knill: December 2000 Source: Translated into this format from data given in http://netlib.bell-labs.com/netlib tetrahedron The [tetrahedron] is a polyhedron with 4 vertices and 4 faces. The dual polyhedron is called tetrahedron. cube The [cube] is a polyhedron with 8 vertices and 6 faces. The dual polyhedron is called octahedron. hexahedron The [hexahedron] is a polyhedron with 8 vertices and 6 faces. The dual polyhedron is called octahedron. octahedron The [octahedron] is a polyhedron with 6 vertices and 8 faces. The dual polyhedron is called cube. dodecahedron The [dodecahedron] is a polyhedron with 20 vertices and 12 faces. The dual polyhedron is called icosahedron. icosahedron The [icosahedron] is a polyhedron with 12 vertices and 20 faces. The dual polyhedron is called dodecahedron. small stellated dodecahedron The [small stellated dodecahedron] is a polyhedron with 12 vertices and 12 faces. The dual polyhedron is called great dodecahedron. great dodecahedron The [great dodecahedron] is a polyhedron with 12 vertices and 12 faces. The dual polyhedron is called small stellated dodecahedron. great stellated dodecahedron The [great stellated dodecahedron] is a polyhedron with 20 vertices and 12 faces. The dual polyhedron is called great icosahedron. great icosahedron The [great icosahedron] is a polyhedron with 12 vertices and 20 faces. The dual polyhedron is called great stellated dodecahedron. truncated tetrahedron The [truncated tetrahedron] is a polyhedron with 12 vertices and 8 faces. The dual polyhedron is called triakis tetrahedron. cuboctahedron The [cuboctahedron] is a polyhedron with 12 vertices and 14 faces. The dual polyhedron is called rhombic dodecahedron.
    [Show full text]
  • Spectral Realizations of Graphs
    SPECTRAL REALIZATIONS OF GRAPHS B. D. S. \DON" MCCONNELL 1. Introduction 2 The boundary of the regular hexagon in R and the vertex-and-edge skeleton of the regular tetrahe- 3 dron in R , as geometric realizations of the combinatorial 6-cycle and complete graph on 4 vertices, exhibit a significant property: Each automorphism of the graph induces a \rigid" isometry of the figure. We call such a figure harmonious.1 Figure 1. A pair of harmonious graph realizations (assuming the latter in 3D). Harmonious realizations can have considerable value as aids to the intuitive understanding of the graph's structure, but such realizations are generally elusive. This note explains and explores a proposition that provides a straightforward way to generate an entire family of harmonious realizations of any graph: A matrix whose rows form an orthogonal basis of an eigenspace of a graph's adjacency matrix has columns that serve as coordinate vectors of the vertices of an harmonious realization of the graph. This is a (projection of a) spectral realization. The hundreds of diagrams in Section 42 illustrate that spectral realizations of graphs with a high degree of symmetry can have great visual appeal. Or, not: they may exist in arbitrarily-high- dimensional spaces, or they may appear as an uninspiring jumble of points in one-dimensional space. In most cases, they collapse vertices and even edges into single points, and are therefore only very rarely faithful. Nevertheless, spectral realizations can often provide useful starting points for visualization efforts. (A basic Mathematica recipe for computing (projected) spectral realizations appears at the end of Section 3.) Not every harmonious realization of a graph is spectral.
    [Show full text]
  • Paper Models of Polyhedra
    Paper Models of Polyhedra Gijs Korthals Altes Polyhedra are beautiful 3-D geometrical figures that have fascinated philosophers, mathematicians and artists for millennia Copyrights © 1998-2001 Gijs.Korthals Altes All rights reserved . It's permitted to make copies for non-commercial purposes only email: [email protected] Paper Models of Polyhedra Platonic Solids Dodecahedron Cube and Tetrahedron Octahedron Icosahedron Archimedean Solids Cuboctahedron Icosidodecahedron Truncated Tetrahedron Truncated Octahedron Truncated Cube Truncated Icosahedron (soccer ball) Truncated dodecahedron Rhombicuboctahedron Truncated Cuboctahedron Rhombicosidodecahedron Truncated Icosidodecahedron Snub Cube Snub Dodecahedron Kepler-Poinsot Polyhedra Great Stellated Dodecahedron Small Stellated Dodecahedron Great Icosahedron Great Dodecahedron Other Uniform Polyhedra Tetrahemihexahedron Octahemioctahedron Cubohemioctahedron Small Rhombihexahedron Small Rhombidodecahedron S mall Dodecahemiododecahedron Small Ditrigonal Icosidodecahedron Great Dodecahedron Compounds Stella Octangula Compound of Cube and Octahedron Compound of Dodecahedron and Icosahedron Compound of Two Cubes Compound of Three Cubes Compound of Five Cubes Compound of Five Octahedra Compound of Five Tetrahedra Compound of Truncated Icosahedron and Pentakisdodecahedron Other Polyhedra Pentagonal Hexecontahedron Pentagonalconsitetrahedron Pyramid Pentagonal Pyramid Decahedron Rhombic Dodecahedron Great Rhombihexacron Pentagonal Dipyramid Pentakisdodecahedron Small Triakisoctahedron Small Triambic
    [Show full text]
  • Wythoffian Skeletal Polyhedra
    Wythoffian Skeletal Polyhedra by Abigail Williams B.S. in Mathematics, Bates College M.S. in Mathematics, Northeastern University A dissertation submitted to The Faculty of the College of Science of Northeastern University in partial fulfillment of the requirements for the degree of Doctor of Philosophy April 14, 2015 Dissertation directed by Egon Schulte Professor of Mathematics Dedication I would like to dedicate this dissertation to my Meme. She has always been my loudest cheerleader and has supported me in all that I have done. Thank you, Meme. ii Abstract of Dissertation Wythoff's construction can be used to generate new polyhedra from the symmetry groups of the regular polyhedra. In this dissertation we examine all polyhedra that can be generated through this construction from the 48 regular polyhedra. We also examine when the construction produces uniform polyhedra and then discuss other methods for finding uniform polyhedra. iii Acknowledgements I would like to start by thanking Professor Schulte for all of the guidance he has provided me over the last few years. He has given me interesting articles to read, provided invaluable commentary on this thesis, had many helpful and insightful discussions with me about my work, and invited me to wonderful conferences. I truly cannot thank him enough for all of his help. I am also very thankful to my committee members for their time and attention. Additionally, I want to thank my family and friends who, for years, have supported me and pretended to care everytime I start talking about math. Finally, I want to thank my husband, Keith.
    [Show full text]
  • Chains of Antiprisms
    Proceedings of Bridges 2015: Mathematics, Music, Art, Architecture, Culture Chains of Antiprisms Tom Verhoeff ∗ Melle Stoel Department of Mathematics and Computer Science Da Costastraat 18 Eindhoven University of Technology 1053 ZC Amsterdam P.O. Box 513 Netherlands 5600 MB Eindhoven, Netherlands [email protected] [email protected] Abstract We prove a property of antiprism chains and show some artwork based on this property. Introduction The sculpture Corkscrew was featured at the Bridges 2014 Art Exhibition [1]. It is constructed from an- tiprisms [4] on regular pentagons, which are either stacked together on their pentagonal faces, or connected on their triangular faces to form zigzag chains. In particular, notice the isosceles ‘triangles’1 consisting of a stack of six antiprisms and two zigzag chains of seven antiprisms. Figure 1 : Sculpture Corkscrew designed and realized by Melle Stoel, constructed from pentago- nal antiprisms At the time when Corkscrew was designed [2], it was only a conjecture that this ‘triangle’ is mathemat- ically precise, that is, that it does not involve any twisting or bending. We will prove the following more general theorem. Consider the antiprism on a regular n-gon, for odd n at least 3. It consists of two regular n-gons connected into a polyhedron by 2n equilateral triangles (see Fig. 2, left). These antiprisms can be connected via diagonally opposite triangles into a zigzag chain, and can be stacked via the n-gons into a tower (see Fig. 2, right). 1There is also a stack of two antiprisms; so, it is more a trapezoid with one quite short edge.
    [Show full text]