Riesz sequences and arithmetic progressions

Given a set $\mathcal{S}$ of positive measure on the circle and a set of integers $\Lambda$, one may consider the family of exponentials $E\left(\Lambda\right):=\left\{ e^{i\lambda t}\right\}_{\lambda\in\Lambda}$ and ask whether it is a Riesz sequence in the space $L^{2}\left(\mathcal{S}\right)$. We focus on this question in connection with some arithmetic properties of the set of frequencies. Improving a result of Bownik and Speegle, we construct a set $\mathcal{S}$ such that $E\left(\Lambda\right)$ is never a Riesz sequence if $\Lambda$ contains arbitrary long arithmetic progressions of length $N$ and step $\ell=O\left(N^{1-\varepsilon}\right)$. On the other hand, we prove that every set $\mathcal{S}$ admits a Riesz sequence $E\left(\Lambda\right)$ such that $\Lambda$ does contain arbitrary long arithmetic progressions of length $N$ and step $\ell=O\left(N\right)$.