Mean value theorems for the S-arithmetic primitive Siegel transforms

Abstract: We develop the theory and properties of primitive unimodular $S$-arithmetic lattices in $\mathbb{Q}_S^d$ by giving integral formulas in the spirit of Siegel's primitive mean value formula and Rogers' and Schmidt's second moment formulas. We then use mean value and second moment formulas in three applications. First, we obtain quantitative estimates for counting primitive $S$-arithmetic lattice points which are used to count primitive integer vectors in $\mathbb{Z}^d$ with congruence conditions. These counting results use asymptotic information for the totient summatory function with added congruence conditions. We next obtain two versions of a quantitative Khintchine-Groshev theorem: counting $\psi$-approximable elements over the primitive set $P(\mathbb{Z}_S^d)$ of $S$-integer vectors and over the primitive set $P(\mathbb{Z}^d)$ of integer vectors with additional congruence conditions. We conclude with an $S$-arithmetic version of logarithm laws for unipotent flows in the spirit of Athreya-Margulis.