Extremal hypercuts and shadows of simplicial complexes

AbstractLet F be an n-vertex forest. An edge e ∉ F is said to be in F’s shadow if F ∪ {e} contains a cycle. It is easy to see that if F is an “almost tree”, i.e., a forest that contains two components, then its shadow contains at least $$\left\lfloor {\frac{{{{(n - 3)}^2}}}{4}} \right\rfloor $$⌊(n−3)24⌋ edges and this is tight. Equivalently, the largest number of edges in an n-vertex cut is $$\left\lfloor {\frac{{{n^2}}}{4}} \right\rfloor $$⌊n24⌋. These notions have natural analogs in higher d-dimensional simplicial complexes which played a key role in several recent studies of random complexes. The higher-dimensional situation differs remarkably from the one-dimensional graph-theoretic case. In particular, the corresponding bounds depend on the underlying field of coefficients. In dimension d = 2 we derive the (tight) analogous theorems. We construct 2-dimensional “ℚ-almost-hypertrees” (defined below) with an empty shadow. We prove that an “$$\mathbb{F}_2$$F2 -almost-hypertree” cannot have an empty shadow, and we determine its least possible size. We also construct large hyperforests whose shadow is empty over every field. For d ≥ 4 even, we construct a d-dimensional $$\mathbb{F}_2$$F2 -almost-hypertree whose shadow has vanishing density.Several intriguing open questions are mentioned as well.

[1]  Matthew Kahle,et al.  The Threshold for Integer Homology in Random d-Complexes , 2013, Discret. Comput. Geom..

[2]  Nathan Linial,et al.  Sum Complexes—a New Family of Hypertrees , 2010, Discret. Comput. Geom..

[3]  Bernt Lindström,et al.  Combinatorial Geometries: Simplicial Matroids , 1987 .

[4]  Gil Kalai,et al.  An extended Euler-Poincaré theorem , 1988 .

[5]  Tomasz Luczak,et al.  Integral Homology of Random Simplicial Complexes , 2016, Discret. Comput. Geom..

[6]  Gil Kalai,et al.  Enumeration ofQ-acyclic simplicial complexes , 1983 .

[7]  Daniel C. Cohen,et al.  Topology of random 2-complexes , 2010, 1006.4229.

[8]  Ilan Newman,et al.  On Multiplicative Lambda-Approximations and Some Geometric Applications , 2013, SIAM J. Comput..

[9]  A. Lubotzky,et al.  RAMANUJAN COMPLEXES OF TYPE Ad , 2007 .

[10]  Ulrich Matthias,et al.  Constructive Upper Bounds for the Turán Number , 1997, Combinatorics, Probability and Computing.

[11]  Nathan Linial,et al.  On the phase transition in random simplicial complexes , 2014, 1410.1281.

[13]  Larry Guth,et al.  2-Complexes with Large 2-Girth , 2018, Discret. Comput. Geom..

[14]  Peter Keevash Surveys in Combinatorics 2011: Hypergraph Turán problems , 2011 .

[15]  Pieter Moree,et al.  Artin's Primitive Root Conjecture – A Survey , 2004, Integers.

[16]  M. Gromov Singularities, Expanders and Topology of Maps. Part 2: from Combinatorics to Topology Via Algebraic Isoperimetry , 2010 .

[17]  Yuri Rabinovich,et al.  On multiplicative λ-approximations and some geometric applications , 2012, SODA.

[18]  Matthew Kahle,et al.  The fundamental group of random 2-complexes , 2007, 0711.2704.

[19]  Art M. Duval,et al.  Simplicial matrix-tree theorems , 2008, 0802.2576.

[20]  Nathan Linial,et al.  Homological Connectivity Of Random 2-Complexes , 2006, Comb..

[21]  Ilan Newman,et al.  Boundaries of Hypertrees, and Hamiltonian Cycles in Simplicial Complexes , 2015 .