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In this article we study domino tilings of a family of finite regions called Aztec diamonds. Every such tiling determines a partition of the Aztec diamond into five sub-regions; in the four outer sub-regions, every tile lines up with nearby…

Combinatorics · Mathematics 2026-04-08 William Jockusch , James Propp , Peter Shor

The expanded Aztec diamond is a generalized version of the Aztec diamond, with an arbitrary number of long columns and long rows in the middle. In this paper, we count the number of domino tilings of the expanded Aztec diamond. The exact…

Combinatorics · Mathematics 2017-11-02 Seungsang Oh

We prove an asymptotic formula for the probability that, if one chooses a domino tiling of a large Aztec diamond at random according to the uniform distribution on such tilings, the tiling will contain a domino covering a given pair of…

Combinatorics · Mathematics 2012-03-15 Henry Cohn , Noam Elkies , James Propp

We study $k$-tilings ($k$-tuples of domino tilings) of the Aztec diamond of rank $m$. We assign a weight to each $k$-tiling, depending on the number of dominos of certain types and the number of "interactions" between the tilings. Employing…

Combinatorics · Mathematics 2024-10-29 Sylvie Corteel , Andrew Gitlin , David Keating

We introduce a family of planar regions, called Aztec diamonds, and study the ways in which these regions can be tiled by dominoes. Our main result is a generating function that not only gives the number of domino tilings of the Aztec…

Combinatorics · Mathematics 2008-02-03 Noam Elkies , Greg Kuperberg , Michael Larsen , James Propp

We get four quartered Aztec diamonds by dividing an Aztec diamond region by two zigzag cuts passing its center. W. Jockusch and J. Propp (in an unpublished work) found that the number of tilings of quartered Aztec diamonds is given by…

Combinatorics · Mathematics 2013-09-27 Tri Lai

We consider asymtotics of a domino tiling model on a class of domains which we call rectangular Aztec diamonds. We prove the Law of Large Numbers for the corresponding height functions and provide explicit formulas for the limit. For a…

Probability · Mathematics 2017-06-23 Alexey Bufetov , Alisa Knizel

Based on a bijection between domino tilings of an Aztec diamond and non-intersecting lattice paths, a simple proof of the Aztec diamond theorem is given in terms of Hankel determinants of the large and small Schr\"oder numbers.

Combinatorics · Mathematics 2007-05-23 Sen-Peng Eu , Tung-Shan Fu

Helfgott and Gessel gave the number of domino tilings of an Aztec Rectangle with defects of size one on the boundary of one side. In this paper we extend this to the case of domino tilings of an Aztec Rectangle with defects on all boundary…

Combinatorics · Mathematics 2017-04-17 Manjil P. Saikia

We study tilings of regions in the square lattice with L-shaped trominoes. Deciding the existence of a tiling with L-trominoes for an arbitrary region in general is NP-complete, nonetheless, we identify restrictions to the problem where it…

Computational Complexity · Computer Science 2020-03-25 Javier T. Akagi , Carlos F. Gaona , Fabricio Mendoza , Manjil P. Saikia , Marcos Villagra

We present a proof of a conjecture about the relationship between Baxter permutations and pairs of alternating sign matrices that are produced from domino tilings of Aztec diamonds. It is shown that if and only if a tiling corresponds to a…

Combinatorics · Mathematics 2010-08-16 Hal Canary

We introduce a family of domino tilings that includes tilings of the Aztec diamond and pyramid partitions as special cases. These tilings live in a strip of $\mathbb{Z}^2$ of the form $1 \leq x-y \leq 2\ell$ for some integer $\ell \geq 1$,…

Combinatorics · Mathematics 2017-09-11 Jérémie Bouttier , Guillaume Chapuy , Sylvie Corteel

The Aztec diamond of order $n$ is the union of lattice squares in the plane intersecting the square $|x|+|y|<n$. The Aztec diamond theorem states that the number of domino tilings of this shape is $2^{n(n+1)/2}$. It was first proved by…

Combinatorics · Mathematics 2014-10-22 Manuel Fendler , Daniel Grieser

We show how to count tilings of Aztec diamonds and hexagons with defects using determinants. In several cases these determinants can be evaluated in closed form. In particular, we obtain solutions to problems 1, 2, and 10 in James Propp's…

Combinatorics · Mathematics 2007-05-23 Harald Helfgott , Ira M. Gessel

We consider domino tilings of the Aztec diamond. Using the Domino Shuffling algorithm introduced by Elkies, Kuperberg, Larsen, and Propp in arXiv:math/9201305, we are able to generate domino tilings uniformly at random. In this paper, we…

Combinatorics · Mathematics 2025-12-10 Marcus Schönfelder

At the free-fermion point, the six-vertex model with domain wall boundary conditions (DWBC) can be related to the Aztec diamond, a domino tiling problem. We study the mapping on the level of complete statistics for general domains and…

Statistical Mechanics · Physics 2011-11-09 Patrik L. Ferrari , Herbert Spohn

Fairly shortly after the publication of the Aztec diamond theorem of Elkies, Kuperberg, Larsen and Propp in 1992, interest arose in finding the number of domino tilings of an Aztec diamond with an ``Aztec window,'' i.e.\ a hole in the shape…

Combinatorics · Mathematics 2025-08-11 Mihai Ciucu

We show that the number of configurations of the 20 Vertex model on certain domains with domain wall type boundary conditions is equal to the number of domino tilings of Aztec-like triangles, proving a conjecture from [P. Di Francesco and…

Combinatorics · Mathematics 2021-02-08 Philippe Di Francesco

In this article we define a generalization of the domino shuffling algorithm for tilings of the Aztec diamond to the interacting $k$-tilings recently introduced by S. Corteel, A. Gitlin, and the first author. We describe the algorithm both…

Combinatorics · Mathematics 2023-03-17 David Keating , Matthew Nicoletti

For various sets of tiles, we count the ways to tile an Aztec diamond of order $n$ using tiles from that set. The resulting function $f(n)$ often has interesting behavior when one looks at $n$ and $f(n)$ modulo powers of 2.

Combinatorics · Mathematics 2024-07-08 James Propp
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