Bosonisation Cohomology: Spin Structure Summation in Every Dimension
Abstract
Gauging fermion parity and summing over spin structures are subtly distinct operations. We introduce 'bosonisation cohomology' groups HBd+2(X) to capture this difference, for theories in spacetime dimension d equipped with maps to some X. Non-trivial classes in HBd+2(X) contain theories for which (-1)F is anomaly-free, but spin structure summation is anomalous. We formulate a sequence of cobordism groups whose failure to be exact is measured by HBd+2(X), and from here we compute it for X=pt. The result is non-trivial only in dimensions d∈ 4Z+2, being due to the presence of gravitational anomalies. The first few are HB4=Z2, probed by a theory of 8 Majorana-Weyl fermions in d=2, then HB8=Z8, HB12=Z16× Z2. We rigorously derive a general formula extending this to every spacetime dimension. Along the way, we compile many general facts about (fermionic and bosonic) anomaly polynomials, and about spin and pin- (co)bordism generators, that we hope might serve as a useful reference for physicists working with these objects. We briefly discuss some physics applications, including how the HB12 class is trivialised in supergravity. Despite the name, and notation, we make no claim that HB(X) actually defines a cohomology theory (in the Eilenberg-Steenrod sense).
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