Henna Koivusalo scite author profile

For the development of a mathematical theory which can be used to rigorously investigate physical properties of quasicrystals, it is necessary to understand regularity of patterns in special classes of aperiodic point sets in Euclidean space. In one dimension, prototypical mathematical models for quasicrystals are provided by Sturmian sequences and by point sets generated by substitution rules. Regularity properties of such sets are well understood, thanks mostly to well known results by Morse and Hedlund, and physicists have used this understanding to study one dimensional random Schrödinger operators and lattice gas models. A key fact which plays an important role in these problems is the existence of a subadditive ergodic theorem, which is guaranteed when the corresponding point set is linearly repetitive.In this paper we extend the one-dimensional model to cut and project sets, which generalize Sturmian sequences in higher dimensions, and which are frequently used in mathematical and physical literature as models for higher dimensional quasicrystals. By using a combination of algebraic, geometric, and dynamical techniques, together with input from higher dimensional Diophantine approximation, we give a complete characterization of all linearly repetitive cut and project sets with cubical windows. We also prove London Mathematical Society* Research supported by EPSRC grants EP/L001462, EP/J00149X, EP/M023540. HK also gratefully acknowledges the support of the Osk. Huttunen foundation.

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Dimension of self-affine sets for fixed translation vectors

Bárány

Käenmäki

Koivusalo

2018

J. London Math. Soc.

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An affine iterated function system (IFS) is a finite collection of affine invertible contractions and the invariant set associated to the mappings is called self‐affine. In 1988, Falconer proved that, for given matrices, the Hausdorff dimension of the self‐affine set is the affinity dimension for Lebesgue almost every translation vectors. Similar statement was proven by Jordan, Pollicott, and Simon in 2007 for the dimension of self‐affine measures. In this article, we have an orthogonal approach. We introduce a class of self‐affine systems in which, given translation vectors, we get the same results for Lebesgue almost all matrices. The proofs rely on Ledrappier–Young theory that was recently verified for affine IFSs by Bárány and Käenmäki, and a new transversality condition, and in particular they do not depend on properties of the Furstenberg measure. This allows our results to hold for self‐affine sets and measures in any Euclidean space.

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Hausdorff dimension of affine random covering sets in torus

Järvenpää¹,

Järvenpää²,

Koivusalo³

et al. 2014

Ann. Inst. H. Poincaré Probab. Statist.

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We calculate the almost sure Hausdorff dimension of the random covering set lim sup n→∞ (g n + ξ n ) in d-dimensional torus T d , where the sets g n ⊂ T d are parallelepipeds, or more generally, linear images of a set with nonempty interior, and ξ n ∈ T d are independent and uniformly distributed random points. The dimension formula, derived from the singular values of the linear mappings, holds provided that the sequences of the singular values are decreasing.

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Constructing bounded remainder sets and cut-and-project sets which are bounded distance to lattices

Haynes

Koivusalo

2016

Isr. J. Math.

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Henna Koivusalo

Dimensions of random affine code tree fractals

A characterization of linearly repetitive cut and project sets

Dimension of self-affine sets for fixed translation vectors

Hausdorff dimension of affine random covering sets in torus

Constructing bounded remainder sets and cut-and-project sets which are bounded distance to lattices

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