⭕Geometric Group Theory Unit 3 – Cayley Graphs and Word Metric
Cayley graphs and word metrics are powerful tools in geometric group theory, visualizing group structures and measuring distances between elements. They bridge algebra and geometry, revealing group properties through graph features like connectedness, symmetry, and curvature.
These concepts have wide-ranging applications, from solving word problems to studying subgroups and classifying groups up to quasi-isometry. Advanced topics like Cayley complexes and asymptotic cones further extend their utility in exploring group geometry and complexity.
Cayley graphs visually represent the structure of a group and how its elements relate to each other through generators
Given a group G and a generating set S, the Cayley graph Γ(G,S) is a directed graph where vertices correspond to elements of G and edges represent multiplication by generators from S
The generating set S is typically chosen to be symmetric, meaning if s∈S, then s−1∈S as well
Cayley graphs are named after the mathematician Arthur Cayley who introduced the concept in the late 19th century
The choice of generating set affects the structure and properties of the resulting Cayley graph
A smaller generating set leads to a sparser graph with fewer edges
A larger generating set results in a denser graph with more connections between vertices
Cayley graphs are regular graphs, meaning every vertex has the same degree (number of incoming and outgoing edges)
The degree of each vertex in a Cayley graph equals the cardinality of the generating set ∣S∣
Group Actions and Cayley Graphs
Group actions play a crucial role in the construction and analysis of Cayley graphs
A group G acts on its Cayley graph Γ(G,S) by left multiplication, meaning for any g∈G and vertex v in the graph, g⋅v is the vertex reached by following the edge labeled g from v
The action of G on its Cayley graph is regular, meaning it acts transitively (any vertex can be mapped to any other vertex) and freely (no non-identity element fixes a vertex)
The regularity of the action implies that Cayley graphs are vertex-transitive, meaning they look the same from the perspective of any vertex
The group action on the Cayley graph preserves the graph's structure and symmetries
Studying the properties of the group action on the Cayley graph can reveal important characteristics of the underlying group, such as its subgroup structure and quotient groups
The Cayley graph can be viewed as a geometric realization of the group action, providing a visual representation of how elements of the group interact with each other
Properties of Cayley Graphs
Cayley graphs have several important properties that make them useful tools in geometric group theory
Connectedness: Cayley graphs are always connected, meaning there is a path between any two vertices in the graph
This follows from the fact that the generating set S generates the entire group G
Vertex-transitivity: As mentioned earlier, Cayley graphs are vertex-transitive due to the regular action of G on the graph
Edge-coloring: Cayley graphs can be edge-colored according to the generators in S, with each generator assigned a distinct color
This coloring is useful for visualizing the structure of the group and studying paths in the graph
Embedding into Cayley graphs: Subgroups of G can be embedded into the Cayley graph as induced subgraphs
The Cayley graph of a subgroup H≤G with respect to the generating set S∩H is an induced subgraph of Γ(G,S)
Cayley graphs are homogeneous spaces, meaning the graph looks the same around any vertex
The automorphism group of a Cayley graph contains a subgroup isomorphic to the original group G, reflecting the symmetries of the graph
Word Metric and Distance
The word metric on a group G with respect to a generating set S is a metric that measures the distance between elements of the group
For any two elements g,h∈G, the word metric distance dS(g,h) is defined as the length of the shortest word in the generators S that represents the element g−1h
In other words, dS(g,h) is the minimum number of generators needed to express g−1h
The word metric can be visualized on the Cayley graph Γ(G,S) as the shortest path distance between vertices corresponding to g and h
The word metric satisfies the axioms of a metric space:
Non-negativity: dS(g,h)≥0 for all g,h∈G
Symmetry: dS(g,h)=dS(h,g) for all g,h∈G
Triangle inequality: dS(g,h)≤dS(g,k)+dS(k,h) for all g,h,k∈G
The word metric depends on the choice of generating set S
Different generating sets may yield different word metric distances between the same pair of elements
The diameter of a Cayley graph is the maximum word metric distance between any two vertices in the graph
The word metric provides a way to study the large-scale geometry of the group and its Cayley graph, as it encodes information about the shortest paths and distances between elements
Geometric Features
Cayley graphs exhibit various geometric features that reflect the properties of the underlying group
Curvature: The curvature of a Cayley graph can be defined using combinatorial or coarse geometric notions
Positively curved Cayley graphs correspond to finite groups
Negatively curved Cayley graphs are associated with hyperbolic groups
Flat Cayley graphs arise from abelian groups or groups with a finite index abelian subgroup
Hyperbolicity: A group is hyperbolic if its Cayley graph satisfies a thin triangles condition
Hyperbolic groups have Cayley graphs that resemble trees on a large scale
The word problem is solvable in linear time for hyperbolic groups using the word metric
Amenability: A group is amenable if it admits a finitely additive, left-invariant probability measure
The Følner condition characterizes amenability in terms of the existence of sets in the Cayley graph with small boundary compared to their size
Growth: The growth function of a group measures how the number of elements in the group grows with respect to the word metric
Polynomial growth corresponds to virtually nilpotent groups (Gromov's theorem)
Exponential growth is associated with non-amenable groups and implies the group contains a free subgroup (Tits alternative)
Ends: The ends of a Cayley graph describe its connectivity at infinity
The number of ends is a quasi-isometry invariant of the group
Groups with more than one end are characterized by Stallings' theorem
Applications in Group Theory
Cayley graphs and the word metric have numerous applications in group theory and related areas
Solving the word problem: The word problem asks whether two words in the generators represent the same group element
The word metric provides a way to solve the word problem by comparing the distances between words
Studying subgroups and quotients: Cayley graphs can be used to study the subgroup structure of a group and visualize quotient groups
Normal subgroups correspond to regular coverings of the Cayley graph
Quotient groups can be realized as Cayley graphs with respect to the image of the generating set under the quotient map
Quasi-isometry classification: Cayley graphs can be used to define a quasi-isometry equivalence relation on groups
Quasi-isometric groups have Cayley graphs that look similar on a large scale
Quasi-isometry invariants, such as growth, ends, and hyperbolicity, can be used to classify groups
Geometric methods in group theory: Cayley graphs provide a bridge between group theory and geometry
Geometric techniques, such as the study of geodesics, boundaries, and actions on metric spaces, can be applied to Cayley graphs to prove results about groups
Connections to other areas: Cayley graphs and the word metric have applications in other areas, such as
Topology (e.g., covering spaces, fundamental groups)
Representation theory (e.g., Kazhdan's property (T))
Examples and Exercises
Example 1: The Cayley graph of the cyclic group Zn with generating set S={1,−1} is a cycle graph on n vertices
Example 2: The Cayley graph of the free group F2=⟨a,b⟩ with generating set S={a,a−1,b,b−1} is an infinite 4-regular tree
Example 3: The Cayley graph of the dihedral group D2n with generating set S={r,s}, where r is rotation and s is reflection, is an n-sided polygon with diagonals
Exercise 1: Prove that the Cayley graph of a group G with respect to a generating set S is connected if and only if S generates G
Exercise 2: Show that the word metric on a group G with respect to a generating set S is left-invariant, i.e., dS(g,h)=dS(kg,kh) for all g,h,k∈G
Exercise 3: Construct the Cayley graph of the quaternion group Q8 with respect to the generating set S={i,j}
Exercise 4: Prove that a group G is finite if and only if its Cayley graph with respect to any generating set is a finite graph
Exercise 5: Show that the Cayley graph of the free abelian group Zn with respect to the standard generating set is the integer lattice in Rn
Advanced Concepts and Extensions
Cayley complexes: Cayley complexes are higher-dimensional analogues of Cayley graphs that encode the structure of a group and its relations
They are constructed by attaching higher-dimensional cells to the Cayley graph according to the relators in a group presentation
Dehn functions: The Dehn function of a group measures the complexity of the word problem by quantifying the area of minimal disk diagrams filling loops in the Cayley complex
The Dehn function is a quasi-isometry invariant and is connected to the geometry and complexity of the group
Automatic groups: A group is automatic if it admits a rational language of normal forms that satisfy certain fellow traveler properties with respect to the word metric
Automatic groups have efficiently solvable word problem and exhibit nice geometric properties
Asymptotic cones: The asymptotic cone of a group is a limit object obtained by rescaling the Cayley graph by larger and larger distances
Asymptotic cones capture the large-scale geometry of the group and are quasi-isometry invariants
Random walks on Cayley graphs: The study of random walks on Cayley graphs provides insights into the geometry and spectral properties of the group
Properties such as the speed of escape, return probabilities, and harmonic functions can be analyzed using random walk techniques
Cayley graphs of semigroups: The concept of Cayley graphs can be extended to semigroups, which are sets with an associative binary operation but not necessarily an identity or inverses
Cayley graphs of semigroups have directed edges and may not be regular or connected
Generalizations to other structures: The idea of Cayley graphs can be generalized to other algebraic structures, such as monoids, rings, and algebras
These generalizations lead to the study of Cayley digraphs, Cayley-Abels graphs, and Schreier coset graphs