Rademacher's Theorem for Calderon-Zygmund-type Spaces
Abstract
Rademacher's Theorem can be interpreted as an almost-everywhere little-o improvement principle: if a function admits a uniform pointwise first-order Lipschitz control at every point, then this control improves to a vanishing one at almost every point. In the language of Calder\'on--Zygmund pointwise spaces, this means that \[ f ∈ T∞1(x) ∀ x ∈ Rd f ∈ t∞1(x) for a.e. x ∈ Rd. \] The purpose of this paper is to establish an analogous almost-everywhere improvement principle in a refined Lp setting. We consider pointwise Calder\'on-Zygmund spaces Tpφ(x) defined via polynomial approximation in Lp with a function parameter φ, allowing for fractional regularity indices and logarithmic corrections through Boyd functions. We prove that, under natural assumptions on φ, the uniform membership \[ f ∈ Tpφ(x) ∀ x ∈ E \] on a measurable set E ⊂ Rd implies an almost-everywhere improvement to a vanishing approximation rate, namely \[ f ∈ tpφ,n+1(x) for a.e. x ∈ E, \] where n < b(φ) ≤ b(φ) < n+1. The proof combines measurability arguments, a generalized Whitney extension theorem, and fine properties of Sobolev spaces. We also show that this result is essentially sharp: in general, one cannot expect almost-everywhere membership in tpφ,n(x) for fractional indices, and explicit counterexamples are provided.
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