English

Topological Mathieu Moonshine

Algebraic Topology 2021-04-20 v2 High Energy Physics - Theory Group Theory K-Theory and Homology

Abstract

We explore the Atiyah-Hirzebruch spectral sequence for the tmf[12]tmf^\bullet[\frac12]-cohomology of the classifying space BM24BM_{24} of the largest Mathieu group M24M_{24}, twisted by a class ωH4(BM24;Z[12])Z3\omega \in H^4(BM_{24};Z[\frac12]) \cong Z_3. Our exploration includes detailed computations of the Z3Z_3-cohomology of M24M_{24} and of the first few differentials in the AHSS. We are specifically interested in the value of tmfω(BM24)[12]tmf^\bullet_\omega(BM_{24})[\frac12] in cohomological degree 27-27. Our main computational result is that tmfω27(BM24)[12]=0tmf^{-27}_\omega(BM_{24})[\frac12] = 0 when ω0\omega \neq 0. For comparison, the restriction map tmfω3(BM24)[12]tmf3(pt)[12]Z3tmf^{-3}_\omega(BM_{24})[\frac12]\to tmf^{-3}(pt)[\frac12] \cong Z_3 is surjective for one of the two nonzero values of ω\omega. Our motivation comes from Mathieu Moonshine. Assuming a well-studied conjectural relationship between TMFTMF and supersymmetric quantum field theory, there is a canonically-defined Co1Co_1-twisted-equivariant lifting [Vˉf][\bar{V}^{f\natural}] of the class {24Δ}TMF24(pt)\{24\Delta\} \in TMF^{-24}(pt), where Co1Co_1 denotes Conway's largest sporadic group. We conjecture that the product [Vˉf]ν[\bar{V}^{f\natural}] \nu, where νTMF3(pt)\nu \in TMF^{-3}(pt) is the image of the generator of tmf3(pt)Z24tmf^{-3}(pt) \cong Z_{24}, does not vanish Co1Co_1-equivariantly, but that its restriction to M24M_{24}-twisted-equivariant TMFTMF does vanish. This conjecture answers some of the questions in Mathieu Moonshine: it implies the existence of a minimally supersymmetric quantum field theory with M24M_{24} symmetry, whose twisted-and-twined partition functions have the same mock modularity as in Mathieu Moonshine. Our AHSS calculation establishes this conjecture "perturbatively" at odd primes. An appendix included mostly for entertainment purposes discusses "\ell-complexes" and their relation to SU(2)\mathrm{SU}(2) Verlinde rings. The case =3\ell=3 is used in our AHSS calculations.

Cite

@article{arxiv.2006.02922,
  title  = {Topological Mathieu Moonshine},
  author = {Theo Johnson-Freyd},
  journal= {arXiv preprint arXiv:2006.02922},
  year   = {2021}
}

Comments

1+57+7 pages. v2 contains small edits

R2 v1 2026-06-23T16:03:37.334Z