On the Moser's Bernstein Theorem

Abstract

In this paper, we prove the following version of the famous Bernstein's theorem: Let X⊂ Rn+k be a closed and connected set with Hausdorff dimension n. Assume that X satisfies the monotonicity formula at p∈ X. Then, the following statements are equivalent: (1) X is an affine linear subspace; (2) X is a definable set that is Lipschitz regular at infinity and its geometric tangent cone at infinity, C(X,∞), is a linear subspace; (3) X is a definable set, blow-spherical regular at infinity and C(X,∞) is a linear subspace; (4) X is a definable set that is Lipschitz normally embedded at infinity and C(X,∞) is a linear subspace; (5) the density of X at infinity is 1. Consequently, we prove the following generalization of Bernstein's theorem: Let X⊂ Rn+1 be a closed and connected set with Hausdorff dimension n. Assume that X satisfies the monotonicity formula at p∈ X and there are compact sets K⊂ Rn and K⊂ Rn+1 such that X K is a minimal hypersurface that is the graph of a C2-smooth function u Rn K R. Assume that u has bounded derivative whenever n>7. Then X is a hyperplane. Several other results are also presented. For example, we generalize the o-minimal Chow's theorem, we prove that any entire complex analytic set that is bi-Lipschitz homeomorphic to a definable set in an o-minimal structure must be an algebraic set. We also obtain that Yau's Bernstein Problem, which says that an oriented stable complete minimal hypersurface in Rn+1 with n≤ 6 must be a hyperplane, holds true whether the hypersurface is a definable set in an o-minimal structure.

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