One of the many wonderful things about K-theory, relative to other generalized cohomology theories, is that it can be defined for not-necessarily-commutative C*-algebras. The resulting construction, in addition to reproducing topological K-theory on compact Hausdorff spaces $X$ via the commutative C*-algebras $C(X)$, can also reproduce equivariant K-theory via crossed products $C(X) \rtimes G$ and twisted K-theory via C*-algebras constructed from the global sections of certain bundles of C*-algebras over $X$, both of which will be noncommutative in general.
It is tempting to wonder if an analogous theory can be developed for tmf. This theory should have (at least) two parts:
- A contravariant functor associating to any compact Hausdorff space $X$ a "higher C*-algebra."
- A covariant functor associating to any "higher C*-algebra" its "operator tmf."
At the very least, the composition of these functors should produce $\text{tmf}(X)$. There are various other things it's natural to ask for. To get equivariant tmf, higher C*-algebras should admit crossed products coming from actions of 2-groups. To get twisted tmf, bundles of certain higher C*-algebras on $X$ should be classified by $H^4(X, \mathbb{Z})$.
Has a proposal for such a theory been given in the literature?
One candidate here is that "higher C*-algebra" should mean tensor C*-category, and that we should associate to a compact Hausdorff space $X$ the tensor C*-category of Hilbert C*-modules over $C(X)$, or equivalently of Riemannian vector bundles over $X$. Then we should take "higher modules" over this object in some refined sense.
Another candidate is that "higher C*-algebra" should mean some variant of conformal nets in the sense of Bartels-Douglas-Henriques, which I guess are more like "higher von Neumann algebras." One reason to believe this is that (at least if I understand what I have been told) there is a conformal net whose automorphism group has the homotopy type $B^3 \mathbb{Z}$, which is the right homotopy type for bundles of that conformal net to be classified by $H^4(X, \mathbb{Z})$. But I don't know what to associate to a compact Hausdorff space.
