Multipliers of the Hilbert spaces of Dirichlet series

Abstract: For a sequence $\mathbf w = {w_j}{j = 2}^\infty$ of positive real numbers, consider the positive semi-definite kernel $\kappa{\mathbf w}(s, u) = \sum_{j = 2}^\infty w_j j^{-s - \overline{u}}$ defined on some right-half plane $\mathbb H_{\rho}$ for a real number $\rho.$ Let $\mathscr H_{\mathbf w}$ denote the reproducing kernel Hilbert space associated with $\kappa_\mathbf w.$ Let \begin{equation*} \delta_{\mathbf w} = \inf\Bigg{\Re(s) : \sum\limits_{\substack{j \geqslant 2 \ \tiny{\textbf{gpf}}(j) \leqslant p_n }} w_j j^{- s} < \infty ~\text{for all}~ n \in \mathbb Z_+\Bigg}, \end{equation*} where ${p_j}{j \geqslant 1}$ is an increasing enumeration of prime numbers and $\textbf{gpf}(n)$ denotes the greatest prime factor of an integer $n \geqslant 2.$ If $\mathbf w$ satisfies \begin{equation*} \sum{\substack{j \geqslant 2\ j | n}} j^{-\delta_\mathbf w} w_j \mu\Big(\frac{n}{j}\Big) \geqslant 0,\quad n \geqslant 2, \end{equation*} where $\mu$ is the M$\ddot{\mbox{o}}$bius function, then the multiplier algebra $\mathcal M(\mathscr H_\mathbf w)$ of $\mathscr H_\mathbf w$ is isometrically isomorphic to the space of all bounded and holomorphic functions on $\mathbb H_\frac{\delta_{\mathbf w}}{2}$ that are representable by a convergent Dirichlet series in some right half plane. As a consequence, we describe the multiplier algebra $\mathcal M(\mathscr H_\mathbf w)$ when $\mathbf w$ is an additive function satisfying $\delta_{\mathbf w} \leqslant 0$ and \begin{align*} \frac{w_{p^{j-1}}}{w_{p^j}} \leqslant p^{-\delta_{\mathbf w}}~\text{for all integers} ~~ j \geqslant 2~\mbox{and all prime numbers}~p. \end{align*} Moreover, we recover a result of Stetler that classifies the multipliers of $\mathscr H_\mathbf w$ when $\mathbf w$ is multiplicative. The proof of the main result is a refinement of the techniques of Stetler.