In mathematics, the Dixmier trace, introduced by , is a non-normal trace on a space of linear operators on a Hilbert space larger than the space of trace class operators. Dixmier traces are examples of singular traces.
Some applications of Dixmier traces to noncommutative geometry are described in .
If H is a Hilbert space, then L<sup>1,âÂÂ</sup>(H) is the space of compact linear operators T on H such that the norm
is finite, where the numbers μ<sub>i</sub>(T) are the eigenvalues of |T| arranged in decreasing order. Let
The Dixmier trace Tr<sub>ω</sub>(T) of T is defined for positive operators T of L<sup>1,âÂÂ</sup>(H) to be
where lim<sub>ω</sub> is a scale-invariant positive "extension" of the usual limit, to all bounded sequences. In other words, it has the following properties:
There are many such extensions (such as a Banach limit of α<sub>1</sub>, α<sub>2</sub>, α<sub>4</sub>, α<sub>8</sub>,...) so there are many different Dixmier traces. As the Dixmier trace is linear, it extends by linearity to all operators of L<sup>1,âÂÂ</sup>(H). If the Dixmier trace of an operator is independent of the choice of lim<sub>ω</sub> then the operator is called measurable.
A trace φ is called normal if φ(sup x<sub>ñ</sub>) = sup φ( x<sub>α</sub>) for every bounded increasing directed family of positive operators. Any normal trace on is equal to the usual trace, so the Dixmier trace is an example of a non-normal trace.
A compact self-adjoint operator with eigenvalues 1, 1/2, 1/3, ... has Dixmier trace equal to 1.
If the eigenvalues ü<sub>i</sub> of the positive operator T have the property that
converges for Re(s)>1 and extends to a meromorphic function near s=1 with at most a simple pole at s=1, then the Dixmier trace of T is the residue at s=1 (and in particular is independent of the choice of ÃÂ).
showed that Wodzicki's noncommutative residue of a pseudodifferential operator on a manifold M of order -dim(M) is equal to its Dixmier trace.