A characterization of compactness via bilinear T1 theorem

Abstract

In this paper we solve a long standing problem about the bilinear T1 theorem to characterize the (weighted) compactness of bilinear Calder\'on-Zygmund operators. Let T be a bilinear operator associated with a standard bilinear Calder\'on-Zygmund kernel. We prove that T can be extended to a compact bilinear operator from Lp1(w1p1) × Lp2(w2p2) to Lp(wp) for all exponents 1p = 1p1 + 1p2>0 with p1, p2 ∈ (1, ∞] and for all weights (w1, w2) ∈ A(p1, p2) if and only if the following hypotheses hold: (H1) T is associated with a compact bilinear Calder\'on-Zygmund kernel, (H2) T satisfies the weak compactness property, and (H3) T(1,1), T*1(1,1), T*2(1,1) ∈ CMO(Rn). This is also equivalent to the endpoint compactness: (1) T is compact from L1(w1) × L1(w2) to L12, ∞(w12) for all (w1, w2) ∈ A(1, 1), or (2) T is compact from L∞(w1∞) × L∞(w2∞) to CMOλ(w∞) for all (w1, w2) ∈ A(∞, ∞). Besides, any of these properties is equivalent to the fact that T admits a compact bilinear dyadic representation. Our main approaches consist of the following new ingredients: (i) a resulting representation of a compact bilinear Calder\'on-Zygmund operator as an average of some compact bilinear dyadic shifts and paraproducts; (ii) extrapolation of endpoint compactness for bilinear operators; and (iii) compactness criterion in weighted Lorentz spaces. Finally, to illustrate the applicability of our result, we demonstrate the hypotheses (H1)-(H3) through examples including bilinear continuous/dyadic paraproducts, bilinear pseudo-differential operators, and bilinear commutators.

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