Kadison transitivity theorem

In mathematics, Kadison transitivity theorem is a result in the theory of C*-algebras that, in effect, asserts the equivalence of the notions of topological irreducibility and algebraic irreducibility of representations of C*-algebras. It implies that, for irreducible representations of C*-algebras, the only non-zero linear invariant manifold is the whole space.

The theorem, proved by Richard Kadison, was surprising as a priori there is no reason to believe that all topologically irreducible representations are also algebraically irreducible.

Statement

A family ${\mathcal {F}}$ of bounded operators on a Hilbert space ${\mathcal {H}}$ is said to act topologically irreducibly when $\{0\}$ and ${\mathcal {H}}$ are the only closed stable subspaces under ${\mathcal {F}}$ . The family ${\mathcal {F}}$ is said to act algebraically irreducibly if $\{0\}$ and ${\mathcal {H}}$ are the only linear manifolds in ${\mathcal {H}}$ stable under ${\mathcal {F}}$ .

Theorem. If the C*-algebra ${\mathfrak {A}}$ acts topologically irreducibly on the Hilbert space ${\mathcal {H}},\{y_{1},\cdots ,y_{n}\}$ is a set of vectors and $\{x_{1},\cdots ,x_{n}\}$ is a linearly independent set of vectors in ${\mathcal {H}}$ , there is an $A$ in ${\mathfrak {A}}$ such that $Ax_{j}=y_{j}$ . If $Bx_{j}=y_{j}$ for some self-adjoint operator $B$ , then $A$ can be chosen to be self-adjoint.

Corollary. If the C*-algebra ${\mathfrak {A}}$ acts topologically irreducibly on the Hilbert space ${\mathcal {H}}$ , then it acts algebraically irreducibly.

References

Kadison, R.V.; Ringrose J.R., Fundamentals of the Theory of Operator Algebras, Vol. I : Elementary Theory, ISBN-13: 978-0821808191