The Hilton-Milner type results of (k, )-sum-free sets in Fpn
Abstract
For a prime p 2 3, it is well known that the largest sum-free subsets of Fpn have size p+13 pn-1, and the extremal sets must be a cuboid of the form \p+13, p+13+1, …, 2p-13\ × Fpn-1 up to isomorphism. Recently, Reiner and Zotova proved a Hilton--Milner type stability result showing that for large p, any sum-free set not contained in the extremal cuboid has size at most p-23 pn-1, and all possible structures attaining this bound were classified. In this paper, we develop a general Hilton--Milner theory for (k,)-sum-free sets in Fpn for k > 1. We determine the maximum size of such sets for all p μ k+ with 2 μ k+-1, and show that the extremal configurations are precisely (μ-1)/2 non-isomorphic cuboids. Beyond the extremal regime, we prove sharp Hilton--Milner type stability results showing that, for all sufficiently large p, a (k,)-sum-free set not contained in any of these extremal cuboids is uniformly bounded away from the maximum by a gap of order pn-1, and we determine the full structure of all sets achieving this second-best bound in several broad parameter ranges. In particular, when 2 μ k+-3 (which is tight), only two structural types occur for all k+ 5; and when μ = 2 or 3, we obtain a complete classification for all k > 1. Our arguments combine additive combinatorics and Fourier-analytic methods, and make use of recent progress toward the long-standing 3k-4 conjecture, highlighting new connections between inverse additive number theory and extremal problems over finite vector spaces.
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