On construction of bounded sets not admitting a general type of Riesz spectrum

Abstract

Despite the recent advances in the theory of exponential Riesz bases, it is yet unknown whether there exists a set S ⊂ Rd which does not admit a Riesz spectrum, meaning that for every ⊂ Rd the set of exponentials e2π i λ · x with λ∈ is not a Riesz basis for L2(S). As a meaningful step towards finding such a set, we construct a set S ⊂ [-12, 12] which does not admit a Riesz spectrum containing a nonempty periodic set with period belonging in α Q+ for any fixed constant α > 0, where Q+ denotes the set of all positive rational numbers. In fact, we prove a slightly more general statement that the set S does not admit a Riesz spectrum containing arbitrarily long arithmetic progressions with a fixed common difference belonging in α N. Moreover, we show that given any countable family of separated sets 1, 2, … ⊂ R with positive upper Beurling density, one can construct a set S ⊂ [-12, 12] which does not admit the sets 1, 2, … as Riesz spectrum. An interesting consequence of our results is the following statement. There is a set V ⊂ [-12, 12] with arbitrarily small Lebesgue measure such that for any N ∈ N and any proper subset I of \ 0, …, N-1 \, the set of exponentials e2π i k x with k ∈ n ∈ I (NZ + n) is not a frame for L2(V). The results are based on the proof technique of Olevskii and Ulanovskii in 2008.