There are infinitely many Hilbert cubes of dimension 3 in the set of squares

Abstract

A Hilbert cube of dimension d is the set of integers \[ H(a0; a1, …, ad)=a0+\0, a1\+·s+\0, ad\=\a0+Σi=1diai:\;i∈\0,1\\. \] Brown, Erdos and Freedman asked whether the maximal dimension of a Hilbert cube in the set S=\n2:\;n∈N\ of integer squares is absolutely bounded or not. Dietmann and Elsholtz proved that if H(a0; a1, …, ad)⊂ S [0, N], then d≤ 7 N for all sufficiently large values of N. Here we prove that there exist at least N1/8 Hilbert cubes H(a0; a1, a2, a3) with a0, a1, a2, a3∈ [0,N] in the set of squares. Moreover, we prove that for each i, j∈\0, 1, 2, 3\ with i<j, the set \aiaj:\;H(a0; a1, a2, a3)⊂ S\ is dense in the set of positive real numbers (in the Euclidean topology).