David Bourne scite author profile

We prove strong crystallization results in two dimensions for an energy that arises in the theory of block copolymers. The energy is defined on sets of points and their weights, or equivalently on the set of atomic measures. It consists of two terms; the first term is the sum of the square root of the weights, and the second is the quadratic optimal transport cost between the atomic measure and the Lebesgue measure.We prove that this system admits crystallization in several different ways: (1) the energy is bounded from below by the energy of a triangular lattice (called T ); (2) if the energy equals that of T , then the measure is a rotated and translated copy of T ; (3) if the energy is close to that of T , then locally the measure is close to a rotated and translated copy of T . These three results require the domain to be a polygon with at most six sides. A fourth result states that the energy of T can be achieved in the limit of large domains, for domains with arbitrary boundaries.The proofs make use of three ingredients. First, the optimal transport cost associates to each point a polygonal cell ; the energy can be bounded from below by a sum over all cells of a function that depends only on the cell. Second, this function has a convex lower bound that is sharp at T . Third, Euler's polytope formula limits the average number of sides of the polygonal cells to six, where six is the number corresponding to the triangular lattice.

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Ollivier--Ricci Idleness Functions of Graphs

Bourne

Cushing

Liu

et al. 2018

SIAM J. Discrete Math.

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We study the Ollivier-Ricci curvature of graphs as a function of the chosen idleness. We show that this idleness function is concave and piecewise linear with at most 3 linear parts, with at most 2 linear parts in the case of a regular graph. We then apply our result to show that the idleness function of the Cartesian product of two regular graphs is completely determined by the idleness functions of the factors.

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Hexagonal Patterns in a Simplified Model for Block Copolymers

Bourne¹,

Peletier²,

Roper³

2014

SIAM J. Appl. Math.

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In this paper we study a new model for patterns in two dimensions, inspired by diblock copolymer melts with a dominant phase. The model is simple enough to be amenable not only to numerics but also to analysis, yet sophisticated enough to reproduce hexagonally packed structures that resemble the cylinder patterns observed in block copolymer experiments.Starting from a sharp-interface continuum model, a nonlocal energy functional involving a Wasserstein cost, we derive the new model using Gamma-convergence in a limit where the volume fraction of one phase tends to zero. The limit energy is defined on atomic measures; in three dimensions the atoms represent small spherical blobs of the minority phase, in two dimensions they represent thin cylinders of the minority phase.We then study minimisers of the limit energy. Numerical minimisation is performed in two dimensions by recasting the problem as a computational geometry problem involving power diagrams. The numerical results suggest that the small particles of the minority phase tend to arrange themselves on a triangular lattice as the number of particles goes to infinity. This is proved in the companion paper [10] and agrees with patterns observed in block copolymer experiments. This is a rare example of a nonlocal energy-driven pattern formation problem in two dimensions where it can be proved that the optimal pattern is periodic.

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Centroidal Power Diagrams, Lloyd's Algorithm, and Applications to Optimal Location Problems

Bourne¹,

Roper²

2015

SIAM J. Numer. Anal.

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In this paper we develop a numerical method for solving a class of optimization problems known as optimal location or quantization problems. The target energy can be written either in terms of atomic measures and the Wasserstein distance or in terms of weighted points and power diagrams (generalized Voronoi diagrams). The latter formulation is more suitable for computation. We show that critical points of the energy are centroidal power diagrams, which are generalizations of centroidal Voronoi tessellations, and that they can be approximated by a generalization of Lloyd's algorithm (Lloyd's algorithm is a common method for finding centroidal Voronoi tessellations). We prove that the algorithm is energy decreasing and prove a convergence theorem. Numerical experiments suggest that the algorithm converges linearly. We illustrate the algorithm in two and three dimensions using simple models of optimal location and crystallization. In particular, we test a conjecture about the optimality of the BCC lattice for a simplified model of block copolymers.

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Laguerre tessellations and polycrystalline microstructures: a fast algorithm for generating grains of given volumes

Bourne

Kok

Roper

et al. 2020

Philosophical Magazine

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We present a fast algorithm for generating Laguerre diagrams with cells of given volumes, which can be used for creating RVEs of polycrystalline materials for computational homogenisation, or for fitting Laguerre diagrams to EBSD or XRD measurements of metals. Given a list of desired cell volumes, we solve a convex optimisation problem to find a Laguerre diagram with cells of these volumes, up to any prescribed tolerance. The algorithm is built on tools from computational geometry and optimal transport theory which, as far as we are aware, have not been applied to microstructure modelling before. We illustrate the speed and accuracy of the algorithm by generating RVEs with user-defined volume distributions with up to 20,000 grains in 3D. We can achieve volume percentage errors of less than 1% in the order of minutes on a standard desktop PC. We also give examples of polydisperse microstructures with bands, clusters and size gradients, and of fitting a Laguerre diagram to 3D EBSD measurements of an IF steel.

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David Bourne

Optimality of the Triangular Lattice for a Particle System with Wasserstein Interaction

Ollivier--Ricci Idleness Functions of Graphs

Hexagonal Patterns in a Simplified Model for Block Copolymers

Centroidal Power Diagrams, Lloyd's Algorithm, and Applications to Optimal Location Problems

Laguerre tessellations and polycrystalline microstructures: a fast algorithm for generating grains of given volumes

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