A sharp variant of the Marcinkiewicz theorem with multipliers in Sobolev spaces of Lorentz type

Abstract

Given a bounded measurable function σ on Rn, we let Tσ be the operator obtained by multiplication on the Fourier transform by σ . Let 0<s1 s2 ·s sn<1 and be a Schwartz function on the real line whose Fourier transform is supported in [-2,-1/2][1/2,2] and which satisfies Σj ∈ Z (2-j )=1 for all ≠ 0. In this work we sharpen the known forms of the Marcinkiewicz multiplier theorem by finding an almost optimal function space with the property that, if the function equation* (1,…, n) Πi=1n (I-∂i2) si2 [ Πi=1n (i) σ(2j11,… , 2jnn)] equation* belongs to it uniformly in j1,… , jn ∈ Z, then Tσ is bounded on Lp( Rn) when |1p-12 | < s1 and 1<p<∞. In the case where si≠ si+1 for all i, it was proved in [Grafakos, Israel J. Math., to appear] that the Lorentz space L 1s1,1 (Rn) is the function space sought. In this work we address the significantly more difficult general case when for certain indices i we might have si=si+1. We obtain a version of the Marcinkiewicz multiplier theorem in which the space L 1s1,1 is replaced by an appropriate Lorentz space associated with a certain concave function related to the number of terms among s2,… , sn that equal s1. Our result is optimal up to an arbitrarily small power of the logarithm in the defining concave function of the Lorentz space.