Quasitrace

In mathematics, especially functional analysis, a quasitrace is a not necessarily additive tracial functional on a C*-algebra. An additive quasitrace is called a trace. It is a major open problem if every quasitrace is a trace.

Definition

A quasitrace on a C*-algebra A is a map τ : A + [ 0 , ] {\displaystyle \tau \colon A_{+}\to [0,\infty ]} such that:

  • τ {\displaystyle \tau } is homogeneous:
τ ( λ a ) = λ τ ( a ) {\displaystyle \tau (\lambda a)=\lambda \tau (a)} for every a A + {\displaystyle a\in A_{+}} and λ [ 0 , ) {\displaystyle \lambda \in [0,\infty )} .
  • τ {\displaystyle \tau } is tracial:
τ ( x x ) = τ ( x x ) {\displaystyle \tau (xx^{*})=\tau (x^{*}x)} for every x A {\displaystyle x\in A} .
  • τ {\displaystyle \tau } is additive on commuting elements:

τ ( a + b ) = τ ( a ) + τ ( b ) {\displaystyle \tau (a+b)=\tau (a)+\tau (b)} for every a , b A + {\displaystyle a,b\in A_{+}} that satisfy a b = b a {\displaystyle ab=ba} .

  • and such that for each n 1 {\displaystyle n\geq 1} the induced map
τ n : M n ( A ) + [ 0 , ] , ( a j , k ) j , k = 1 , . . . , n τ ( a 11 ) + . . . τ ( a n n ) {\displaystyle \tau _{n}\colon M_{n}(A)_{+}\to [0,\infty ],(a_{j,k})_{j,k=1,...,n}\mapsto \tau (a_{11})+...\tau (a_{nn})}

has the same properties.

A quasitrace τ {\displaystyle \tau } is:

  • bounded if
sup { τ ( a ) : a A + , a 1 } < . {\displaystyle \sup\{\tau (a):a\in A_{+},\|a\|\leq 1\}<\infty .}
  • normalized if
sup { τ ( a ) : a A + , a 1 } = 1. {\displaystyle \sup\{\tau (a):a\in A_{+},\|a\|\leq 1\}=1.}
  • lower semicontinuous if
{ a A + : τ ( a ) t } {\displaystyle \{a\in A_{+}:\tau (a)\leq t\}} is closed for each t [ 0 , ) {\displaystyle t\in [0,\infty )} .

Variants

  • A 1-quasitrace is a map A + [ 0 , ] {\displaystyle A_{+}\to [0,\infty ]} that is just homogeneous, tracial and additive on commuting elements, but does not necessarily extend to such a map on matrix algebras over A. If a 1-quasitrace extends to the matrix algebra M n ( A ) {\displaystyle M_{n}(A)} , then it is called a n-quasitrace. There are examples of 1-quasitraces that are not 2-quasitraces. One can show that every 2-quasitrace is automatically a n-quasitrace for every n 1 {\displaystyle n\geq 1} . Sometimes in the literature, a quasitrace means a 1-quasitrace and a 2-quasitrace means a quasitrace.

Properties

  • A quasitrace that is additive on all elements is called a trace.
  • Uffe Haagerup showed that every quasitrace on a unital, exact C*-algebra is additive and thus a trace. The article of Haagerup [1] was circulated as handwritten notes in 1991 and remained unpublished until 2014. Blanchard and Kirchberg removed the assumption of unitality in Haagerup's result.[2] As of today (August 2020) it remains an open problem if every quasitrace is additive.
  • Joachim Cuntz showed that a simple, unital C*-algebra is stably finite if and only if it admits a dimension function. A simple, unital C*-algebra is stably finite if and only if it admits a normalized quasitrace. An important consequence is that every simple, unital, stably finite, exact C*-algebra admits a tracial state.
  • Every quasitrace on a von Neumann algebra is a trace.

Notes

  1. ^ (Haagerup 2014)
  2. ^ Blanchard, Kirchberg, 2004, Remarks 2.29(i)

References

  • Blanchard, Etienne; Kirchberg, Eberhard (February 2004). "Non-simple purely infinite C∗-algebras: the Hausdorff case" (PDF). Journal of Functional Analysis. 207 (2): 461–513. doi:10.1016/j.jfa.2003.06.008.
  • Haagerup, Uffe (2014). "Quasitraces on Exact C*-algebras are Traces". C. R. Math. Rep. Acad. Sci. Canada. 36: 67–92.