Generalized positive scalar curvature on spin$^c$ manifolds (2404.00703v3)
Abstract: Let $(M,L)$ be a (compact) non-spin spin$c$ manifold. Fix a Riemannian metric $g$ on $M$ and a connection $A$ on $L$, and let $D_L$ be the associated spin$c$ Dirac operator. Let $R{tw}_{(g,A)}:=R_g + 2ic(\Omega)$ be the twisted scalar curvature (which takes values in the endomorphisms of the spinor bundle), where $R_g$ is the scalar curvature of $g$ and $2ic(\Omega)$ comes from the curvature $2$-form $\Omega$ of the connection $A$. Then the Lichnerowicz-Schr\"odinger formula for the square of the Dirac operator takes the form $D_L2 =\nabla*\nabla+\frac{1}{4}R{tw}_{(g,A)}$. In a previous work we proved that a closed non-spin simply-connected spin$c$-manifold $(M,L)$ of dimension $n\geq 5$ admits a pair $(g,A)$ such that $R{tw}_{(g,A)}>0$ if and only if the index $\alphac(M,L):=\text{ind}\, D_L$ vanishes in $K_n$. In this paper we introduce a scalar-valued generalized scalar curvature $R{gen}_{(g,A)}:=R_g - 2|\Omega|{op}$, where $|\Omega|{op}$ is the pointwise operator norm of Clifford multiplication $c(\Omega)$, acting on spinors. We show that the positivity condition on the operator $R{tw}_{(g,A)}$ is equivalent to the positivity of the scalar function $R{gen}_{g,A}$. We prove a corresponding trichotomy theorem concerning the curvature $R{gen}_{(g,A)}$, and study its implications. We also show that the space $\mathcal{R}{gen+}(M,L)$ of pairs $(g,A)$ with $R{gen}_{(g,A)}>0$ has non-trivial topology, and address a conjecture about non-triviality of the ``index difference'' map.