Non-Euclidean unification of isoperimetric profiles and grand Lebesgue-Sobolev scales

Abstract

Let (X,d,μ) be a complete separable metric measure space satisfying a doubling condition and a (1,1)-Poincaré inequality. We develop a rigorous framework unifying two lines of analysis: the isoperimetric-profile approach of Coulhon-Grigor'yan-Levin CGL2003 and the grand/small Lebesgue-Sobolev scale introduced by Fiorenza-Formica-Gogatishvili FFG2018. An explicit profile-to-scale transform , defined via an inverse integral of , converts geometric data into grand Lebesgue parameters. Sharp, up to universal constants, embeddings W1,1(X) GX with explicit constants (Theorem thmmain). A converse: controlled grand embeddings imply explicit lower bounds on (Theorem thmconverse). Concrete examples in genuinely non-Euclidean settings: the Heisenberg group H1, a model manifold with logarithmic volume growth, and Gaussian measure on n treated as a locally doubling space. All arguments are carried out on general metric measure spaces without reference to charts or a smooth structure; the gradient is the upper gradient in the sense of Heinonen-Koskela, and perimeter is the outer Minkowski content.