Compact Quantum Metric Spaces from Free Graph Algebras

Abstract

Starting with a vertex-weighted pointed graph (,μ,v0), we form the free loop algebra S0 defined in Hartglass-Penneys' article on canonical C*-algebras associated to a planar algebra. Under mild conditions, S0 is a non-nuclear simple C*-algebra with unique tracial state. There is a canonical polynomial subalgebra A⊂ S0 together with a Dirac number operator N such that (A, L2A,N) is a spectral triple. We prove the Haagerup-type bound of Ozawa-Rieffel to verify (S0, A, N) yields a compact quantum metric space in the sense of Rieffel. We give a weighted analog of Benjamini-Schramm convergence for vertex-weighted pointed graphs. As our C*-algebras are non-nuclear, we adjust the Lip-norm coming from N to utilize the finite dimensional filtration of A. We then prove that convergence of vertex-weighted pointed graphs leads to quantum Gromov-Hausdorff convergence of the associated adjusted compact quantum metric spaces. As an application, we apply our construction to the Guionnet-Jones-Shyakhtenko (GJS) C*-algebra associated to a planar algebra. We conclude that the compact quantum metric spaces coming from the GJS C*-algebras of many infinite families of planar algebras converge in quantum Gromov-Hausdorff distance.