Linear bounds for constants in Gromov's systolic inequality and related results

Abstract

Let Mn be a closed Riemannian manifold. Larry Guth proved that there exists c(n) with the following property: if for some r>0 the volume of each metric ball of radius r is less than (r c(n))n, then there exists a continuous map from Mn to a (n-1)-dimensional simplicial complex such that the inverse image of each point can be covered by a metric ball of radius r in Mn. It was previously proven by Gromov that this result implies two by now famous Gromov's inequalities: Fill Rad(Mn)≤ c(n)vol(Mn)1 n and, if Mn is essential, then also sys1(Mn)≤ 6c(n)vol(Mn)1 n with the same constant c(n). Here sys1(Mn) denotes the length of a shortest non-contractible closed curve in Mn. We prove that these results hold with c(n)=(n! 2)1 n≤ n 2. We demonstrate that for essential Riemannian manifolds sys1(Mn) ≤ n\ vol1 n(Mn). All previously known upper bounds for c(n) were exponential in n. Moreover, we present a qualitative improvement: In Guth's theorem the assumption that the volume of every metric ball of radius r is less than (r c(n))n can be replaced by a weaker assumption that for every point x∈ Mn there exists a positive (x)≤ r such that the volume of the metric ball of radius (x) centered at x is less than ((x) c(n))n (for c(n)=(n! 2)1 n). Also, if X is a boundedly compact metric space such that for some r>0 and an integer n≥ 1 the n-dimensional Hausdorff content of each metric ball of radius r in X is less than (r 4n)n, then there exists a continuous map from X to a (n-1)-dimensional simplicial complex such that the inverse image of each point can be covered by a metric ball of radius r.