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1. Density of monochromatic infinite subgraphs II

   https://doi.org/10.1017/fms.2025.42  

   Corsten, Jan; DeBiasio, Louis; McKenney, Paul (January 2025, Forum of Mathematics, Sigma)

   Abstract In 1967, Gerencsér and Gyárfás [16] proved a result which is considered the starting point of graph-Ramsey theory: In every 2-coloring of$$K_n$$, there is a monochromatic path on$$\lceil (2n+1)/3\rceil $$vertices, and this is best possible. There have since been hundreds of papers on graph-Ramsey theory with some of the most important results being motivated by a series of conjectures of Burr and Erdős [2, 3] regarding the Ramsey numbers of trees (settled in [31]), graphs with bounded maximum degree (settled in [5]), and graphs with bounded degeneracy (settled in [23]). In 1993, Erdős and Galvin [13] began the investigation of a countably infinite analogue of the Gerencsér and Gyárfás result: What is the largestdsuch that in every$$2$$-coloring of$$K_{\mathbb {N}}$$there is a monochromatic infinite path with upper density at leastd? Erdős and Galvin showed that$$2/3\leq d\leq 8/9$$, and after a series of recent improvements, this problem was finally solved in [7] where it was shown that$$d={(12+\sqrt {8})}/{17}$$. This paper begins a systematic study of quantitative countably infinite graph-Ramsey theory, focusing on infinite analogues of the Burr-Erdős conjectures. We obtain some results which are analogous to what is known in finite case, and other (unexpected) results which have no analogue in the finite case. 

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2. The k -core in percolated dense graph sequences

   https://doi.org/10.1017/jpr.2024.66  

   Bayraktar, Erhan; Chakraborty, Suman; Zhang, Xin (March 2025, Journal of Applied Probability)

   Abstract We determine the order of thek-core in a large class of dense graph sequences. Let$$G_n$$be a sequence of undirected,n-vertex graphs with edge weights$$\{a^n_{i,j}\}_{i,j \in [n]}$$that converges to a graphon$$W\colon[0,1]^2 \to [0,+\infty)$$in the cut metric. Keeping an edge (i,j) of$$G_n$$with probability$${a^n_{i,j}}/{n}$$independently, we obtain a sequence of random graphs$$G_n({1}/{n})$$. Using a branching process and the theory of dense graph limits, under mild assumptions we obtain the order of thek-core of random graphs$$G_n({1}/{n})$$. Our result can also be used to obtain the threshold of appearance of ak-core of ordern. 

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3. Ramsey numbers of hypergraphs with a given size

   https://doi.org/10.1017/S0305004124000409  

   BRADAČ, DOMAGOJ; FOX, JACOB; SUDAKOV, BENNY (January 2025, Mathematical Proceedings of the Cambridge Philosophical Society)

   Abstract Theq-colour Ramsey number of ak-uniform hypergraphHis the minimum integerNsuch that anyq-colouring of the completek-uniform hypergraph onNvertices contains a monochromatic copy ofH. The study of these numbers is one of the central topics in Combinatorics. In 1973, Erdős and Graham asked to maximise the Ramsey number of a graph as a function of the number of its edges. Motivated by this problem, we study the analogous question for hypergaphs. For fixed$$k \ge 3$$and$$q \ge 2$$we prove that the largest possibleq-colour Ramsey number of ak-uniform hypergraph withmedges is at most$$\mathrm{tw}_k(O(\sqrt{m})),$$where tw denotes the tower function. We also present a construction showing that this bound is tight for$$q \ge 4$$. This resolves a problem by Conlon, Fox and Sudakov. They previously proved the upper bound for$$k \geq 4$$and the lower bound for$$k=3$$. Although in the graph case the tightness follows simply by considering a clique of appropriate size, for higher uniformities the construction is rather involved and is obtained by using paths in expander graphs. 

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4. Bipartite-ness under smooth conditions

   https://doi.org/10.1017/S0963548323000019  

   Jiang, Tao; Longbrake, Sean; Ma, Jie (February 2023, Combinatorics, Probability and Computing)

   Abstract Given a family$$\mathcal{F}$$of bipartite graphs, theZarankiewicz number$$z(m,n,\mathcal{F})$$is the maximum number of edges in an$$m$$by$$n$$bipartite graph$$G$$that does not contain any member of$$\mathcal{F}$$as a subgraph (such$$G$$is called$$\mathcal{F}$$-free). For$$1\leq \beta \lt \alpha \lt 2$$, a family$$\mathcal{F}$$of bipartite graphs is$$(\alpha,\beta )$$-smoothif for some$$\rho \gt 0$$and every$$m\leq n$$,$$z(m,n,\mathcal{F})=\rho m n^{\alpha -1}+O(n^\beta )$$. Motivated by their work on a conjecture of Erdős and Simonovits on compactness and a classic result of Andrásfai, Erdős and Sós, Allen, Keevash, Sudakov and Verstraëte proved that for any$$(\alpha,\beta )$$-smooth family$$\mathcal{F}$$, there exists$$k_0$$such that for all odd$$k\geq k_0$$and sufficiently large$$n$$, any$$n$$-vertex$$\mathcal{F}\cup \{C_k\}$$-free graph with minimum degree at least$$\rho (\frac{2n}{5}+o(n))^{\alpha -1}$$is bipartite. In this paper, we strengthen their result by showing that for every real$$\delta \gt 0$$, there exists$$k_0$$such that for all odd$$k\geq k_0$$and sufficiently large$$n$$, any$$n$$-vertex$$\mathcal{F}\cup \{C_k\}$$-free graph with minimum degree at least$$\delta n^{\alpha -1}$$is bipartite. Furthermore, our result holds under a more relaxed notion of smoothness, which include the families$$\mathcal{F}$$consisting of the single graph$$K_{s,t}$$when$$t\gg s$$. We also prove an analogous result for$$C_{2\ell }$$-free graphs for every$$\ell \geq 2$$, which complements a result of Keevash, Sudakov and Verstraëte. 

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5. Counting independent sets in structured graphs

   https://doi.org/10.1017/S0963548325000124  

   Bucić, Matija; Chudnovsky, Maria; Codsi, Julien (July 2025, Combinatorics, Probability and Computing)

   Abstract Counting independent sets in graphs and hypergraphs under a variety of restrictions is a classical question with a long history. It is the subject of the celebrated container method which found numerous spectacular applications over the years. We consider the question of how many independent sets we can have in a graph under structural restrictions. We show that any$$n$$-vertex graph with independence number$$\alpha$$without$$bK_a$$as an induced subgraph has at most$$n^{O(1)} \cdot \alpha ^{O(\alpha )}$$independent sets. This substantially improves the trivial upper bound of$$n^{\alpha },$$whenever$$\alpha \le n^{o(1)}$$and gives a characterisation of graphs forbidding which allows for such an improvement. It is also in general tight up to a constant in the exponent since there exist triangle-free graphs with$$\alpha ^{\Omega (\alpha )}$$independent sets. We also prove that if one in addition assumes the ground graph is chi-bounded one can improve the bound to$$n^{O(1)} \cdot 2^{O(\alpha )}$$which is tight up to a constant factor in the exponent. 

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