On Hausdorff dimensions of k-point configuration sets and Elekes-R\'onyai type theorems
Abstract
We prove a ''dimension expansion'' version of the Elekes-R\'onyai theorem for trivariate real analytic functions: If f is a trivariate real analytic function, then f is either locally of the form g(h(x)+k(y)+l(z)), or the following is true: whenever a Borel set A⊂R has Hausdorff dimension α∈ (12,1), f(A× A× A) has dimension significantly larger than that of A, i.e. align* Hf(A× A× A)≥ α+(α), for some (α)>0, align* Moreover, if α>23, f(A× A× A) has positive Lebesgue measure. This is a considerable extension of the result established by Koh, T. Pham, and Shen (J. Funct. Anal. 286 (2024)). We also obtain an alternative proof and an improvement for the Elekes-R\'onyai type theorem for bivariate real analytic functions established by Raz and Zahl (Geom. Funct. Anal. 34 (2024)). We derive these from more general results, showing that various k-point configuration sets of thin sets have positive Lebesgue measure by exploiting the optimal L2-based Sobolev estimates for the associated family of Fourier integral operators. Extending the framework developed by Greenleaf, Iosevich, and Taylor (Mathematika 68 (2022), Math. Z. 306 (2024)) to prove Mattila-Sj\"olin type theorems, we obtain Falconer-type results for many configuration sets on which the method would be vacuous if demanding nonempty interior. In particular, when k=2, we generalize the Falconer-type result for metric functions in Rd satisfying strong non-vanishing curvature conditions established by Eswarathasan, Iosevich, and Taylor (Adv. Math. 228 (2011)) and the asymmetric Mattila-Sj\"olin type results of Greenleaf, Iosevich, and Taylor (J. Geom. Anal. 31 (2021)) to a broader class of smooth functions of asymmetric form.
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