Geometric Group Theory

Geometric Group Theory Unit 7 – CAT(0) Spaces and Groups

CAT(0) spaces are metric spaces that generalize non-positive curvature from Riemannian geometry. They have unique geodesics, convex metric balls, and triangles that are "thinner" than their Euclidean counterparts. These properties make CAT(0) spaces powerful tools in geometric group theory. Groups acting on CAT(0) spaces, called CAT(0) groups, exhibit interesting geometric and algebraic properties. The boundary theory of CAT(0) spaces provides insights into asymptotic behavior, while examples like symmetric spaces and cube complexes connect to various areas of mathematics and applications.

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Definition and Basic Properties

  • CAT(0) spaces are metric spaces that satisfy certain curvature conditions, generalizing non-positive curvature from Riemannian geometry
  • Formally, a metric space (X,d)(X,d) is CAT(0) if for any geodesic triangle Δ(x,y,z)\Delta(x,y,z) in XX and a comparison triangle Δ(x,y,z)\overline{\Delta}(\overline{x},\overline{y},\overline{z}) in Euclidean space, the CAT(0) inequality holds: d(p,q)dE(p,q)d(p,q) \leq d_E(\overline{p},\overline{q}) for any points p,qp,q on Δ\Delta and their comparison points p,q\overline{p},\overline{q} on Δ\overline{\Delta}
    • Intuitively, triangles in CAT(0) spaces are "thinner" than their Euclidean counterparts
  • CAT(0) spaces are uniquely geodesic, meaning any two points are connected by a unique geodesic segment
  • Convexity is a key property of CAT(0) spaces
    • Metric balls are convex
    • The distance function is convex along geodesics
  • CAT(0) spaces are contractible, implying they have trivial topology (homotopy equivalent to a point)
  • Complete CAT(0) spaces are often called Hadamard spaces, honoring the work of Jacques Hadamard on non-positively curved manifolds

Metric Space Structure

  • As metric spaces, CAT(0) spaces inherit various properties and tools from metric geometry
  • The metric induces a topology, allowing for the study of continuity, convergence, and compactness
  • Completeness is an important property, ensuring the existence of limits and fixed points
    • Many results assume the CAT(0) space is complete (Hadamard space)
  • The metric also induces a length structure, enabling the study of paths, curves, and geodesics
  • Angles can be defined using the cosine law, generalizing the Euclidean notion
    • Alexandrov angles compare the angle between geodesics to the angle in a Euclidean comparison triangle
  • The Gromov product, defined as (xy)z=12(d(x,z)+d(y,z)d(x,y))(x|y)_z = \frac{1}{2}(d(x,z) + d(y,z) - d(x,y)), measures the "overlap" between geodesics from zz to xx and yy, playing a crucial role in boundary theory and hyperbolic geometry

Curvature Conditions

  • CAT(0) spaces are defined by a curvature condition comparing triangles to their Euclidean counterparts
  • The CAT(0) inequality d(p,q)dE(p,q)d(p,q) \leq d_E(\overline{p},\overline{q}) captures the idea of non-positive curvature
    • Triangles in CAT(0) spaces are "thinner" than Euclidean triangles
  • An equivalent condition is the Bruhat-Tits non-positive curvature inequality involving the midpoint of a geodesic segment
  • CAT(0) is a global condition, while the related notion of non-positive curvature (NPC) is local
    • NPC spaces are locally CAT(0) but may not be globally CAT(0) (branching may occur)
  • The Cartan-Hadamard theorem states that complete, simply connected Riemannian manifolds of non-positive sectional curvature are CAT(0)
    • Provides a rich source of examples (symmetric spaces, hyperbolic spaces)
  • Alexandrov's Patchwork Globalization theorem allows constructing CAT(0) spaces by gluing together non-positively curved spaces satisfying certain conditions

Geodesics and Triangles

  • Geodesics are locally distance-minimizing paths generalizing straight lines in Euclidean space
  • In CAT(0) spaces, geodesics are globally distance-minimizing, unique, and vary continuously with endpoints
  • The CAT(0) condition is often phrased in terms of geodesic triangles and their comparison triangles in Euclidean space
    • For any points p,qp,q on a geodesic triangle Δ(x,y,z)\Delta(x,y,z), the CAT(0) inequality compares their distance to the distance between corresponding points p,q\overline{p},\overline{q} on the Euclidean comparison triangle Δ(x,y,z)\overline{\Delta}(\overline{x},\overline{y},\overline{z})
  • Geodesic triangles in CAT(0) spaces satisfy a number of properties generalizing the Euclidean case
    • The angle sum is at most π\pi
    • The Alexandrov angle between geodesics is well-defined and satisfies triangle inequalities
    • Trigonometric formulas (sine law, cosine law) hold for geodesic triangles
  • Geodesic triangles are key to understanding the geometry and topology of CAT(0) spaces
    • Used to prove contractibility, fixed point theorems, and boundary theory

Isometries and Group Actions

  • Isometries are distance-preserving maps between metric spaces, forming a group under composition
  • The isometry group Isom(X)\text{Isom}(X) of a CAT(0) space XX captures its symmetries and rigidity properties
    • Often infinite-dimensional but shares properties with Lie groups (proper, locally compact)
  • Group actions on CAT(0) spaces, particularly isometric actions, are a central object of study
    • An action GXG \curvearrowright X is a homomorphism from GG to Isom(X)\text{Isom}(X)
  • Proper actions (cocompact or properly discontinuous) are well-behaved and allow for a geometric study of the group GG
    • Cocompact actions have compact quotient space X/GX/G
    • Properly discontinuous actions have discrete orbits and well-defined quotient
  • The Cartan Fixed Point Theorem guarantees a fixed point for any bounded isometric action on a complete CAT(0) space
    • Generalizes the Brouwer Fixed Point Theorem and has applications to group theory and topology
  • The Flat Torus Theorem classifies isometric actions on CAT(0) spaces with a Euclidean subspace invariant under a Zn\mathbb{Z}^n subgroup
    • Key tool in geometric group theory and rigidity theory

Boundary Theory

  • The visual boundary X\partial X of a CAT(0) space XX consists of equivalence classes of geodesic rays, capturing the asymptotic geometry
    • Geodesic rays are equivalent if they stay within bounded distance of each other
  • The cone topology on X=XX\overline{X} = X \cup \partial X generalizes the topology of the closed unit ball
    • Makes X\overline{X} compact if XX is proper (closed balls are compact)
  • The Gromov product extends to the boundary, allowing for a metric on X\partial X
    • The Gromov product at infinity is defined as (xy)=supzXlim infxx,yy(xy)z(x|y)_\infty = \sup\limits_{z \in X} \liminf\limits_{x' \to x, y' \to y} (x'|y')_z
  • Isometric actions on XX extend to actions on the boundary X\partial X
    • Fixed points on the boundary are often easier to find and correspond to "directions moved" by the isometry
  • The Tits metric dTd_T on the boundary, defined using Alexandrov angles, captures the geometry of directions
    • CAT(0) boundaries with the Tits metric are themselves CAT(1) spaces
  • Flat subspaces in XX correspond to spherical subbuildings in the Tits boundary (X,dT)(\partial X, d_T)
    • Key to the Flat Torus Theorem and rigidity results

Examples and Applications

  • Euclidean spaces Rn\mathbb{R}^n and hyperbolic spaces Hn\mathbb{H}^n are primary examples of CAT(0) spaces
  • Symmetric spaces and Bruhat-Tits buildings associated with semisimple Lie groups and algebraic groups are important examples in Lie theory and number theory
    • The visual boundary of a symmetric space identifies with the spherical building at infinity
  • CAT(0) cube complexes, obtained by gluing Euclidean cubes along faces, are key examples in geometric group theory
    • Hyperplanes and half-spaces allow for a combinatorial study
    • Arise in the study of right-angled Artin groups, Coxeter groups, and small cancellation theory
  • Gromov hyperbolic spaces are CAT(0) spaces with additional "negative curvature" properties
    • Boundary is a quasi-metric space, often fractal in nature
    • Include classical hyperbolic spaces, hyperbolic groups, and random groups
  • The Weil-Petersson metric on Teichmüller space is CAT(0), connecting to the geometry of moduli spaces of Riemann surfaces
  • Phylogenetic tree space, used in evolutionary biology, has a CAT(0) metric related to the space of probability distributions

Advanced Topics and Open Problems

  • Isometry groups of CAT(0) spaces are often infinite-dimensional, but share properties with Lie groups
    • The Hilbert-Smith conjecture asks if locally compact groups acting effectively on manifolds must be Lie groups
  • Quasi-isometries are maps between metric spaces that preserve large-scale geometry
    • Gromov hyperbolic groups are classified up to quasi-isometry
    • Quasi-isometric rigidity results aim to classify groups and spaces up to quasi-isometry
  • The Rank Rigidity Theorem characterizes irreducible CAT(0) spaces of higher rank
    • Euclidean buildings or symmetric spaces associated with higher-rank semisimple groups
  • Mostow's Strong Rigidity Theorem states that homotopy equivalent compact hyperbolic manifolds are isometric
    • Generalizations to CAT(0) spaces and buildings using the geometry of the boundary
  • The Tits Alternative states that finitely generated linear groups either contain a non-abelian free subgroup or are virtually solvable
    • Versions exist for isometry groups of CAT(0) spaces and CAT(0) groups
  • Boundaries of CAT(0) groups are often difficult to compute explicitly
    • Conjectured to be non-equivariantly homeomorphic to the Menger curve in many cases
  • The existence of a cocompact CAT(0) space is conjectured to be equivalent to various analytic and geometric properties of groups (Novikov conjecture, Baum-Connes conjecture, Haagerup property)


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AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.