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We consider the hard-core model on a finite square grid graph with stochastic Glauber dynamics parametrized by the inverse temperature 
$\beta$. We investigate how the transition between its two maximum-occupancy configurations takes place in the low-temperature regime 
$\beta \to \infty$ in the case of periodic boundary conditions. The hard-core constraints and the grid symmetry make the structure of the critical configurations for this transition, also known as essential saddles, very rich and complex. We provide a comprehensive geometrical characterization of these configurations that together constitute a bottleneck for the Glauber dynamics in the low-temperature limit. In particular, we develop a novel isoperimetric inequality for hard-core configurations with a fixed number of particles and show how the essential saddles are characterized not only by the number of particles but also their geometry.
We consider the constrained-degree percolation model in a random environment (CDPRE) on the square lattice. In this model, each vertex v has an independent random constraint 
$\kappa_v$ which takes the value 
$j\in \{0,1,2,3\}$ with probability 
$\rho_j$. The dynamics is as follows: at time 
$t=0$ all edges are closed; each edge e attempts to open at a random time 
$U(e)\sim \mathrm{U}(0,1]$, independently of all the other edges. It succeeds if at time U(e) both its end vertices have degrees strictly smaller than their respective constraints. We obtain exponential decay of the radius of the open cluster of the origin at all times when its expected size is finite. Since CDPRE is dominated by Bernoulli percolation, this result is meaningful only if the supremum of all values of t for which the expected size of the open cluster of the origin is finite is larger than 
$\frac12$. We prove this last fact by showing a sharp phase transition for an intermediate model.
We answer the following question: if the occupied (or vacant) set of a planar Poisson Boolean percolation model contains a crossing of an 
$n\times n$ square, how wide is this crossing? The answer depends on whether we consider the critical, sub-, or super-critical regime, and is different for the occupied and vacant sets.
We introduce gradient flow aggregation, a random growth model. Given existing particles 
$\{x_1,\ldots,x_n\} \subset \mathbb{R}^2$, a new particle arrives from a random direction at 
$\infty$ and flows in direction of the vector field 
$\nabla E$ where 
$ E(x) = \sum_{i=1}^{n}{1}/{\|x-x_i\|^{\alpha}}$, 
$0 < \alpha < \infty$. The case 
$\alpha = 0$ refers to the logarithmic energy 
${-}\sum\log\|x-x_i\|$. Particles stop once they are at distance 1 from one of the existing particles, at which point they are added to the set and remain fixed for all time. We prove, under a non-degeneracy assumption, a Beurling-type estimate which, via Kesten’s method, can be used to deduce sub-ballistic growth for 
$0 \leq \alpha < 1$, 
$\text{diam}(\{x_1,\ldots,x_n\}) \leq c_{\alpha} \cdot n^{({3 \alpha +1})/({2\alpha + 2})}$. This is optimal when 
$\alpha = 0$. The case 
$\alpha = 0$ leads to a ‘round’ full-dimensional tree. The larger the value of 
$\alpha$, the sparser the tree. Some instances of the higher-dimensional setting are also discussed.
We study the low-temperature 
$(2+1)$D solid-on-solid model on 
with zero boundary conditions and nonnegative heights (a floor at height 
$0$). Caputo et al. (2016) established that this random surface typically admits either 
$\mathfrak h $ or 
$\mathfrak h+1$ many nested macroscopic level line loops 
$\{\mathcal L_i\}_{i\geq 0}$ for an explicit 
$\mathfrak h\asymp \log L$, and its top loop 
$\mathcal L_0$ has cube-root fluctuations: For example, if 
$\rho (x)$ is the vertical displacement of 
$\mathcal L_0$ from the bottom boundary point 
$(x,0)$, then 
$\max \rho (x) = L^{1/3+o(1)}$ over 
. It is believed that rescaling 
$\rho $ by 
$L^{1/3}$ and 
$I_0$ by 
$L^{2/3}$ would yield a limit law of a diffusion on 
$[-1,1]$. However, no nontrivial lower bound was known on 
$\rho (x)$ for a fixed 
$x\in I_0$ (e.g., 
$x=\frac L2$), let alone on 
$\min \rho (x)$ in 
$I_0$, to complement the bound on 
$\max \rho (x)$. Here, we show a lower bound of the predicted order 
$L^{1/3}$: For every 
$\epsilon>0$, there exists 
$\delta>0$ such that 
$\min _{x\in I_0} \rho (x) \geq \delta L^{1/3}$ with probability at least 
$1-\epsilon $. The proof relies on the Ornstein–Zernike machinery due to Campanino–Ioffe–Velenik and a result of Ioffe, Shlosman and Toninelli (2015) that rules out pinning in Ising polymers with modified interactions along the boundary. En route, we refine the latter result into a Brownian excursion limit law, which may be of independent interest. We further show that in a 
$ K L^{2/3}\times K L^{2/3}$ box with boundary conditions 
$\mathfrak h-1,\mathfrak h,\mathfrak h,\mathfrak h$ (i.e., 
$\mathfrak h-1$ on the bottom side and 
$\mathfrak h$ elsewhere), the limit of 
$\rho (x)$ as 
$K,L\to \infty $ is a Ferrari–Spohn diffusion.
Let 
$\mathcal{V}$ and 
$\mathcal{U}$ be the point sets of two independent homogeneous Poisson processes on 
$\mathbb{R}^d$. A graph 
$\mathcal{G}_\mathcal{V}$ with vertex set 
$\mathcal{V}$ is constructed by first connecting pairs of points (v, u) with 
$v\in\mathcal{V}$ and 
$u\in\mathcal{U}$ independently with probability 
$g(v-u)$, where g is a non-increasing radial function, and then connecting two points 
$v_1,v_2\in\mathcal{V}$ if and only if they have a joint neighbor 
$u\in\mathcal{U}$. This gives rise to a random intersection graph on 
$\mathbb{R}^d$. Local properties of the graph, including the degree distribution, are investigated and quantified in terms of the intensities of the underlying Poisson processes and the function g. Furthermore, the percolation properties of the graph are characterized and shown to differ depending on whether g has bounded or unbounded support.
We define the co-spectral radius of inclusions 
${\mathcal S}\leq {\mathcal R}$ of discrete, probability- measure-preserving equivalence relations as the sampling exponent of a generating random walk on the ambient relation. The co-spectral radius is analogous to the spectral radius for random walks on 
$G/H$ for inclusion 
$H\leq G$ of groups. For the proof, we develop a more general version of the 2–3 method we used in another work on the growth of unimodular random rooted trees. We use this method to show that the walk growth exists for an arbitrary unimodular random rooted graph of bounded degree. We also investigate how the co-spectral radius behaves for hyperfinite relations, and discuss new critical exponents for percolation that can be defined using the co-spectral radius.
We obtain the asymptotic behaviour of the longest increasing/non-decreasing subsequences in a random uniform multiset permutation in which each element in 
$\{1,\dots,n\}$ occurs k times, where k may depend on n. This generalises the famous Ulam–Hammersley problem of the case 
$k=1$. The proof relies on poissonisation and on a careful non-asymptotic analysis of variants of the Hammersley–Aldous–Diaconis particle system.
We consider bond percolation on high-dimensional product graphs 
$G=\square _{i=1}^tG^{(i)}$, where 
$\square$ denotes the Cartesian product. We call the 
$G^{(i)}$ the base graphs and the product graph 
$G$ the host graph. Very recently, Lichev (J. Graph Theory, 99(4):651–670, 2022) showed that, under a mild requirement on the isoperimetric properties of the base graphs, the component structure of the percolated graph 
$G_p$ undergoes a phase transition when 
$p$ is around 
$\frac{1}{d}$, where 
$d$ is the average degree of the host graph.
In the supercritical regime, we strengthen Lichev’s result by showing that the giant component is in fact unique, with all other components of order 
$o(|G|)$, and determining the sharp asymptotic order of the giant. Furthermore, we answer two questions posed by Lichev (J. Graph Theory, 99(4):651–670, 2022): firstly, we provide a construction showing that the requirement of bounded degree is necessary for the likely emergence of a linear order component; secondly, we show that the isoperimetric requirement on the base graphs can be, in fact, super-exponentially small in the dimension. Finally, in the subcritical regime, we give an example showing that in the case of irregular high-dimensional product graphs, there can be a polynomially large component with high probability, very much unlike the quantitative behaviour seen in the Erdős-Rényi random graph and in the percolated hypercube, and in fact in any regular high-dimensional product graphs, as shown by the authors in a companion paper (Percolation on high-dimensional product graphs. arXiv:2209.03722, 2022).
We determine almost sure limits of rescaled intrinsic volumes of the construction steps of fractal percolation in 
${\mathbb R}^d$ for any dimension 
$d\geq 1$. We observe a factorization of these limit variables which allows one, in particular, to determine their expectations and covariance structure. We also show the convergence of the rescaled expectations and variances of the intrinsic volumes of the construction steps to the expectations and variances of the limit variables, and we give rates for this convergence in some cases. These results significantly extend our previous work, which addressed only limits of expectations of intrinsic volumes.
$\boldsymbol{d}\boldsymbol\gt \textbf{8}$
A spread-out lattice animal is a finite connected set of edges in 
$\{\{x,y\}\subset \mathbb{Z}^d\;:\;0\lt \|x-y\|\le L\}$. A lattice tree is a lattice animal with no loops. The best estimate on the critical point 
$p_{\textrm{c}}$ so far was achieved by Penrose (J. Stat. Phys. 77, 3–15, 1994) : 
$p_{\textrm{c}}=1/e+O(L^{-2d/7}\log L)$ for both models for all 
$d\ge 1$. In this paper, we show that 
$p_{\textrm{c}}=1/e+CL^{-d}+O(L^{-d-1})$ for all 
$d\gt 8$, where the model-dependent constant 
$C$ has the random-walk representationwhere 
\begin{align*} C_{\textrm{LT}}=\sum _{n=2}^\infty \frac{n+1}{2e}U^{*n}(o),&& C_{\textrm{LA}}=C_{\textrm{LT}}-\frac 1{2e^2}\sum _{n=3}^\infty U^{*n}(o), \end{align*}
$U^{*n}$ is the 
$n$-fold convolution of the uniform distribution on the 
$d$-dimensional ball 
$\{x\in{\mathbb R}^d\;: \|x\|\le 1\}$. The proof is based on a novel use of the lace expansion for the 2-point function and detailed analysis of the 1-point function at a certain value of 
$p$ that is designed to make the analysis extremely simple.
