Title: Sup-norm bounds for Jacobi cusp forms

Abstract: In this article, we give bounds for the natural invariant norm of cusp forms of real weight $k$ and character $\chi$ for any cofinite Fuchsian subgroup $\Gamma\subset\mathrm{SL}_{2}(\mathbb{R})$. Using the representation of Jacobi cusp forms of integral weight $k$ and index $m$ for the modular group $\Gamma_{0}=\mathrm{SL}_{2}(\mathbb{Z})$ as linear combinations of modular forms of weight $k-\frac{1}{2}$ for some congruence subgroup of $\Gamma_{0}$ (depending on $m$) and suitable Jacobi theta functions, we derive bounds for the natural invariant norm of these Jacobi cusp forms. More specifically, letting $J_{k,m}^{\mathrm{cusp}}(\Gamma_{0})$ denote the complex vector space of Jacobi cusp forms under consideration and $\Vert\cdot\Vert_{\mathrm{Pet}}$ the pointwise Petersson norm on $J_{k,m}^{\mathrm{cusp}}(\Gamma_{0})$, we prove that for given $\epsilon>0$, the bound \begin{align*} \sup_{(\tau,z)\in\mathbb{H}\times\mathbb{C}}\Vert f(\tau,z)\Vert_{\mathrm{Pet}}=O_{\epsilon}\big(k^{\frac{3}{4}}m^{\frac{3}{2}+\epsilon}\big) \end{align*} holds for any $f\in J_{k,m}^{\mathrm{cusp}}(\Gamma_{0})$, which is normalized with respect to the Petersson inner product, where the implied constant depends only on the choice of $\epsilon>0$.