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A famous problem in birational geometry is to determine when the birational automorphism group of a Fano variety is finite. The Noether–Fano method has been the main approach to this problem. The purpose of this paper is to give a new approach to the problem by showing that in every positive characteristic, there are Fano varieties of arbitrarily large index with finite (or even trivial) birational automorphism group. To do this, we prove that these varieties admit ample and birationally equivariant line bundles. Our result applies the differential forms that Kollár produces on 
$p$-cyclic covers in characteristic 
$p > 0$.
We show that every orbispace satisfying certain mild hypotheses has ‘enough’ vector bundles. It follows that the 
$K$-theory of finite rank vector bundles on such orbispaces is a cohomology theory. Global presentation results for smooth orbifolds and derived smooth orbifolds also follow.
Celebrated theorems of Roth and of Matoušek and Spencer together show that the discrepancy of arithmetic progressions in the first 
$n$ positive integers is 
$\Theta (n^{1/4})$. We study the analogous problem in the 
$\mathbb {Z}_n$ setting. We asymptotically determine the logarithm of the discrepancy of arithmetic progressions in 
$\mathbb {Z}_n$ for all positive integer 
$n$. We further determine up to a constant factor the discrepancy of arithmetic progressions in 
$\mathbb {Z}_n$ for many 
$n$. For example, if 
$n=p^k$ is a prime power, then the discrepancy of arithmetic progressions in 
$\mathbb {Z}_n$ is 
$\Theta (n^{1/3+r_k/(6k)})$, where 
$r_k \in \{0,1,2\}$ is the remainder when 
$k$ is divided by 
$3$. This solves a problem of Hebbinghaus and Srivastav.
We prove new results on the distribution of rational points on ramified covers of abelian varieties over finitely generated fields 
$k$ of characteristic zero. For example, given a ramified cover 
$\pi : X \to A$, where 
$A$ is an abelian variety over 
$k$ with a dense set of 
$k$-rational points, we prove that there is a finite-index coset 
$C \subset A(k)$ such that 
$\pi (X(k))$ is disjoint from 
$C$. Our results do not seem to be in the range of other methods available at present; they confirm predictions coming from Lang's conjectures on rational points, and also go in the direction of an issue raised by Serre regarding possible applications to the inverse Galois problem. Finally, the conclusions of our work may be seen as a sharp version of Hilbert's irreducibility theorem for abelian varieties.