Real rank (C*-algebras)

In mathematics, the real rank of a C*-algebra is a noncommutative analogue of Lebesgue covering dimension. The notion was first introduced by Lawrence G. Brown and Gert K. Pedersen.^[1]

Definition

The real rank of a unital C*-algebra A is the smallest non-negative integer n, denoted RR(A), such that for every (n + 1)-tuple (x₀, x₁, ... ,x_n) of self-adjoint elements of A and every ε > 0, there exists an (n + 1)-tuple (y₀, y₁, ... ,y_n) of self-adjoint elements of A such that $\sum _{i=0}^{n}y_{i}^{2}$ is invertible and $\lVert \sum _{i=0}^{n}(x_{i}-y_{i})^{2}\rVert <\varepsilon$ . If no such integer exists, then the real rank of A is infinite. The real rank of a non-unital C*-algebra is defined to be the real rank of its unitization.

Comparisons with dimension

If X is a locally compact Hausdorff space, then RR(C₀(X)) = dim(X), where dim is the Lebesgue covering dimension of X. As a result, real rank is considered a noncommutative generalization of dimension, but real rank can be rather different when compared to dimension. For example, most noncommutative tori have real rank zero, despite being a noncommutative version of the two-dimensional torus. For locally compact Hausdorff spaces, being zero-dimensional is equivalent to being totally disconnected. The analogous relationship fails for C*-algebras; while AF-algebras have real rank zero, the converse is false. Formulas that hold for dimension may not generalize for real rank. For example, Brown and Pedersen conjectured that RR(A ⊗ B) ≤ RR(A) + RR(B), since it is true that dim(X × Y) ≤ dim(X) + dim(Y). They proved a special case that if A is AF and B has real rank zero, then A ⊗ B has real rank zero. But in general their conjecture is false, there are C*-algebras A and B with real rank zero such that A ⊗ B has real rank greater than zero.^[2]

Real rank zero

C*-algebras with real rank zero are of particular interest. By definition, a unital C*-algebra has real rank zero if and only if the invertible self-adjoint elements of A are dense in the self-adjoint elements of A. This condition is equivalent to the previously studied conditions:

(FS) The self-adjoint elements of A with finite spectrum are dense in the self-adjoint elements of A.
(HP) Every hereditary C*-subalgebra of A has an approximate identity consisting of projections.

This equivalence can be used to give many examples of C*-algebras with real rank zero including AW*-algebras, Bunce–Deddens algebras,^[3] and von Neumann algebras. More broadly, simple unital purely infinite C*-algebras have real rank zero including the Cuntz algebras and Cuntz–Krieger algebras. Since simple graph C*-algebras are either AF or purely infinite, every simple graph C*-algebra has real rank zero.

Having real rank zero is a property closed under taking direct limits, hereditary C*-subalgebras, and strong Morita equivalence. In particular, if A has real rank zero, then M_n(A) the algebra of n × n matrices over A has real rank zero for any integer n ≥ 1.

References

↑ Brown, Lawrence G; Pedersen, Gert K (July 1991). "C*-algebras of real rank zero". Journal of Functional Analysis. 99 (1): 131–149. doi:10.1016/0022-1236(91)90056-B. Zbl 0776.46026.
↑ Kodaka, Kazunori; Osaka, Hiroyuki (July 1995). "Real Rank of Tensor Products of C*-algebras". Proceedings of the American Mathematical Society. 123 (7): 2213–2215. doi:10.1090/S0002-9939-1995-1264820-4. Zbl 0835.46053.
↑ Blackadar, Bruce; Kumjian, Alexander (March 1985). "Skew Products of Relations and the Structure of Simple C*-Algebras". Mathematische Zeitschrift. 189 (1): 55–63. doi:10.1007/BF01246943. Zbl 0613.46049.

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