Abstract
AbstractThe geometric sieve for densities is a very convenient tool proposed by Poonen and Stoll (and independently by Ekedahl) to compute the density of a given subset of the integers. In this paper we provide an effective criterion to find all higher moments of the density (e.g. the mean, the variance) of a subset of a finite dimensional free module over the ring of algebraic integers of a number field. More precisely, we provide a geometric sieve that allows the computation of all higher moments corresponding to the density, over a general number field K. This work advances the understanding of geometric sieve for density computations in two ways: on one hand, it extends a result of Bright, Browning and Loughran, where they provide the geometric sieve for densities over number fields; on the other hand, it extends the recent result on a geometric sieve for expected values over the integers to both the ring of algebraic integers and to moments higher than the expected value. To show how effective and applicable our method is, we compute the density, mean and variance of Eisenstein polynomials and shifted Eisenstein polynomials over number fields. This extends (and fully covers) results in the literature that were obtained with ad-hoc methods.
Funder
HORIZON EUROPE Marie Sklodowska-Curie Actions
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung
National Science Foundation
Publisher
Springer Science and Business Media LLC
Subject
Algebra and Number Theory
Reference26 articles.
1. Baake, M., Moody, R.V., Peter, A.B.: Pleasants. Diffraction from visible lattice points and $$k$$th power free integers. Discrete Mathem. 221(1-3), 3–42 (2000)
2. Bhargava, M.: The geometric sieve and the density of squarefree values of invariant polynomials (2014). arXiv preprint arXiv:1402.0031
3. Bright, M., Browning, T.D., Loughran, D.: Failures of weak approximation in families. Compos. Math. 152(7), 1435–1475 (2016)
4. Browning, T.D., Heath-Brown, R.: The geometric sieve for quadrics. In: Forum Mathematicum, Vol. 33, pp. 147–165. De Gruyter (2021)
5. Scott Cassels, J.W.: An Introduction to the Geometry of Numbers. Springer, New York (2012)