ALGEBRAIC AND COMBINATORIAL ASPECTS OF TWO SYMMETRIC POLYTOPES A thesis presented to the faculty of San Francisco State University In partial fulfillment of A The Requirements for 56 The Degree c30l^ Master of Arts . '■* i-,? In Mathematics by Anna Maria Schindler San Francisco, California August 2017 Copyright by Anna Maria Schindler 2017 CERTIFICATION OF APPROVAL I certify that I have read ALGEBRAIC AND COMBINATORIAL AS PECTS OF TWO SYMMETRIC POLYTOPES by Anna Maria Schindler and that in ray opinion this work meets the criteria for approving a thesis submitted in partial fulfillment of the requirements for the degree: Master of Arts in Mathematics at San Francisco State University. Federico Ardila Professor of Mathematics ikl Matthias Beck Professor of Mathematics ALGEBRAIC AND COMBINATORIAL ASPECTS OF TWO SYMMETRIC POLYTOPES Anna Maria Schindler San Francisco State University 2017 Equivariant Ehrhart theory is an extension of Ehrhart theory that considers lattice polytopes under group actions. Ehrhart theory tells us that the lattice points in a lattice (or rational) polytope are counted by polynomials (or quasi-polynomials). In the equivariant analog, we consider the Ehrhart theory of the subsets of the polytope fixed by the action. This first part of this thesis, a joint project with Andres Vindas, focuses on the equivariant Ehrhart theory of IIn under the action of Sn. We prove that the fixed sub-polytopes of IIn are zonotopes and are combinatorially equivalent to permutahedra. We provide vertex and hyperplane descriptions. We also compute the equivariant Ehrhart theory for 111,112,113, and II4. This thesis also includes work in spectral graph theory. Motivated by a tropical approach to the Hodge conjecture, we compute the spectrum of the tropical Laplacian matrix of the root polytope An, confirming a special case of a result of Babaee and Huh. I certify that the Abstract is a correct representation of the content of this thesis. Q J JU ___________JJ n . W l a u Chair, Thesis Committee Date ACKNOWLEDGMENTS First, I would like to thank my thesis advisor, Federico Ardila. I can truly say that the geometry class I took with Federico my very first semester at San Francisco State University is a big part of the reason that I applied to the master’s program here. Federico has provided me with so much insight and encouragement over the past few years, for which I am very grateful. Federico’s research meetings were collaborative in nature, so this thesis has been touched by many, dxl would like to thank all of the fellow students who listened to my thoughts and shared their own insights. In particular, I would like to thank my research partner, Andres Vindas, with whom part of this thesis is joint work. Andres excitement and motivation about the project was invaluable. I would also like to thank our dear friend John Guo, who was there for support and insight throughout the whole thesis process. Finally, I would like to thank my thesis committee, Serkan Hosten and Matthias Beck, whose input was essential to the finished product. TABLE OF CONTENTS 1 Introduction.............................................................................................................. 1 1.1 Equivariant Ehrhart theory ........................................................................ 1 1.2 The tropical Laplacian of An ......................................................................... 6 2 The fixed sub-polytopes of the permutahedron................................................ 9 2.1 Background..................................................................................................... 9 2.1.1 Discrete geometry............................................................................... 9 2.1.2 Ehrhart theory.................................................................................. 14 2.1.3 The symmetric group........................................................................ 19 2.1.4 The permutahedron............................................................................ 21 2.1.5 The Ehrhart theory of the permutahedron......................................24 2.1.6 Representation theory.........................................................................26 2.1.7 Equivariant Ehrhart theory................................................................29 2.2 Results...................................................................................................................32 2.2.1 The set-up................................................................................................33 2.2.2 The fixed sub-polytopes of Iln ............................................................34 2.2.3 The equivariant Ehrhart theory of 111,112,113, and II4 ....................53 3 The tropical Laplacian of the root polytope An ...................................................60 3.1 Background..................................................................................................... 61 3.1.1 Results......................................................................................................63 vi Bibliography LIST OF TABLES Table Page viii LIST OF FIGURES Figure Page 1.1 (n4)(i3)........................................................................................ 4 1.2 n3.................................................................................................................... 4 1.3 n3............................................................................................... 7 2.1 n3 ............................................................................................ 15 2.2 n3, 2II3, and 3II3 ................................................................................................16 2.3 Lattice points in II3, 2II3, and 3II3 ........................................................... 17 2.4 n4.............................................................................................................................22 2.5 Labeled forests on three vertices........................................................................25 2.6 The fixed sub-polytope (Il4)(13).........................................................................35 2.7 The fixed sub-polytope (Il4)(i3) and its vertices.............................................38 2.8 (II4) (12)....................................................................................................................54 2.9 (n4)(i23)...................................................................................................................59 3.1 The polytope A4...................................................................................................69 3.2 The graph of A\....................................................................................................70 3.3 The directed graph A'n associated with A4......................................................70 1 Chapter 1 Introduction 1.1 Equivariant Ehrhart theory Equivariant Ehrhart theory was first established by Alan Stapledon in his 2011 paper. [13] The theory extends Ehrhart theory by studying lattice polytopes together with the action of groups. Ehrhart theory is concerned with enumerating the lattice points in the dilates of a polytope P. Let mP denote the dilation of P by a positive integer m, i.e, mP — {mx : x E P}. Eugene Ehrhart’s remarkable result is that, if P is a lattice polytope, the number of lattice points in mP is counted by a polynomial in m, called the Ehrhart polynomial of P. If P is a rational polytope, then the number of lattice points in mP is counted by a quasi-polynomial. The generating function, called the Ehrhart series of a
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