dp convergence and ε-regularity theorems for entropy and scalar curvature lower bounds

Abstract

Consider a sequence of Riemannian manifolds (Mni,gi) with scalar curvatures and entropies bounded below by small constants Ri,μi ≥-εi. The goal of this paper is to understand notions of convergence and the structure of limits for such spaces. Even in the seemingly rigid case εi 0, we construct examples showing that such a sequence may converge wildly in the Gromov-Hausdorff or Intrinsic Flat sense. On the other hand, we will see that these classical notions of convergence are the incorrect ones to consider. Indeed, even a metric space is the wrong underlying category to be working on. Instead, we introduce dp convergence, a weaker notion of convergence that is valid for a class of rectifiable Riemannian spaces. These rectifiable spaces have well-behaved topology, measure theory, and analysis, though potentially there will be no reasonably associated distance function. Under the dp notion of closeness, a space with almost nonnegative scalar curvature and small entropy bounds must in fact be close to Euclidean space; this will constitute our ε-regularity theorem. More generally, we have a compactness theorem saying that sequences of Riemannian manifolds (Mni,gi) with small lower scalar curvature and entropy bounds Ri,μi ≥ -ε must dp converge to such a rectifiable Riemannian space X. Comparing to the first paragraph, the distance functions of Mi may be degenerating, even though in a well-defined sense the analysis cannot be. Applications for manifolds with small scalar and entropy lower bounds include an L∞-Sobolev embedding and apriori Lp scalar curvature bounds for p<1.