Graph operations and a unified method for kinds of Tur\'an-type problems on paths, cycles and matchings
Pith reviewed 2026-05-24 04:55 UTC · model grok-4.3
The pith
Any feasible graph parameter is maximized by specific join graphs among 2-connected C_{≥k}-free graphs, connected P_k-free graphs, or M_{k+1}-free graphs.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Let G be a 2-connected n-vertex C_{≥k}-free graph with maximum feasible P(G). Then G belongs to the family G¹_{n,k} = {K_s ∨ ((n-k+s)K_1 ∪ K_{k-2s}) : 2 ≤ s ≤ ⌊(k-1)/2⌋}. Analogous statements hold for connected P_k-free graphs, where the extremal graphs are K_s ∨ ((n-k+s+1)K_1 ∪ K_{k-2s-1}) for 1 ≤ s ≤ ⌊k/2⌋-1, and for connected M_{k+1}-free graphs, where the extremal graphs are K_s ∨ ((n-2k+s-1)K_1 ∪ K_{2k-2s+1}) for 1 ≤ s ≤ k when n ≥ 2k+2 (and the complete graph when n = 2k+1).
What carries the argument
A feasible parameter together with the Kelmans operation, which forces any maximizer to be a join of cliques and independent sets by the two monotonicity conditions.
If this is right
- The ordinary Turán number ex(n, C_{≥k}) and its generalizations follow by taking P to count copies of a fixed subgraph.
- Maximum degree powers and other degree-based invariants are determined by the same structural result.
- Upper bounds on the adjacency spectral radius and signless-Laplacian spectral radius of C_{≥k}-free graphs are obtained by setting P equal to those radii.
- The same families solve the corresponding problems for P_k-free and M_{k+1}-free graphs without additional case analysis.
Where Pith is reading between the lines
- The method supplies a single proof template that simultaneously settles many previously separate extremal problems once the two feasibility axioms are verified for the chosen parameter.
- If a new parameter satisfies the same two axioms, its extremal graphs are immediately known without repeating the structural argument.
- The technique may extend to other hereditary families closed under the Kelmans operation, yielding analogous classifications.
Load-bearing premise
The parameter must satisfy both monotonicity conditions that define feasibility.
What would settle it
Exhibit a feasible parameter P together with an n-vertex graph G that avoids the relevant forbidden subgraphs, is not isomorphic to any member of the claimed extremal family, yet satisfies P(G) strictly larger than P on every graph in the family.
read the original abstract
Let $G$ be a connected graph and $\mathcal{P}(G)$ a graph parameter. We say that $\mathcal{P}(G)$ is feasible if $\mathcal{P}(G)$ satisfies the following properties: (I) $\mathcal{P}(G)\leq \mathcal{P}(G_{uv})$, if $G_{uv}=G[u\to v]$ for any $u,v$, where $G_{uv}$ is the graph obtained by applying Kelmans operation from $u$ to $v$; (II) $\mathcal{P}(G) <\mathcal{P}(G+e)$ for any edge $e\notin E(G)$. Let $P_k$ be a path of order $k$, $\mathcal{C}_{\geq k}$ the set of all cycles of length at least $k$ and $M_{k+1}$ a matching containing $k+1$ independent edges. In this paper, we mainly prove the following three results: (i) Let $n\geq k\geq 5$ and let $t=\left\lfloor\frac{k-1}{2}\right\rfloor$. Let $G$ be a $2$-connected $n$-vertex $\mathcal{C}_{\geq k}$-free graph with the maximum $\mathcal{P}(G)$ where $\mathcal{P}(G)$ is feasible. Then, $G\in \mathcal{G}^1_{n,k}=\{W_{n,k,s}=K_{s}\vee ((n-k+s)K_1\cup K_{k-2s}): 2\leq s\leq t\}$. (ii) Let $n\geq k\geq 4$ and let $t=\left\lfloor\frac{k}{2}\right\rfloor-1$. Let $G$ be a connected $n$-vertex $P_{k}$-free graph with the maximum $\mathcal{P}(G)$ where $\mathcal{P}(G)$ is feasible. Then, $G\in \mathcal{G}^2_{n,k}=\{W_{n,k-1,s}=K_{s}\vee ((n-k+s+1)K_1\cup K_{k-2s-1}): 1\leq s\leq t\}.$ (iii) Let $G$ be a connected $n$-vertex $M_{k+1}$-free graph with the maximum $\mathcal{P}(G)$ where $\mathcal{P}(G)$ is feasible. Then, $G\cong K_n$ when $n=2k+1$ and $G\in \mathcal{G}^3_{n,k}=\{K_s\vee ((n-2k+s-1)K_1\cup K_{2k-2s+1}):1\leq s\leq k\}$ when $n\geq 2k+2$. Directly derived from these three main results, we obtain a series of applications in Tur\'an-type problems, generalized Tur\'an-type problems, powers of graph degrees in extremal graph theory, and problems related to spectral radius, and signless Laplacian spectral radius in spectral graph theory.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper defines a graph parameter P as feasible if it is non-decreasing under Kelmans operations (P(G) ≤ P(G_uv)) and strictly increases upon edge addition (P(G) < P(G+e)). It proves three structural theorems: for 2-connected n-vertex C_{≥k}-free graphs (n≥k≥5), the maximizer of feasible P belongs to the family G¹_{n,k} of graphs K_s ∨ ((n-k+s)K_1 ∪ K_{k-2s}) for 2≤s≤⌊(k-1)/2⌋; for connected n-vertex P_k-free graphs (n≥k≥4), the maximizer is in G²_{n,k} = {K_s ∨ ((n-k+s+1)K_1 ∪ K_{k-2s-1}) : 1≤s≤⌊k/2⌋-1}; and for connected n-vertex M_{k+1}-free graphs, the maximizer is K_n when n=2k+1 and otherwise in G³_{n,k} = {K_s ∨ ((n-2k+s-1)K_1 ∪ K_{2k-2s+1}) : 1≤s≤k}. These characterizations are used to derive applications to Turán-type problems, degree powers, and spectral radii.
Significance. If the characterizations hold, the paper supplies a unified method that reduces many extremal problems (edge extremal, generalized Turán, spectral) to verifying that the target parameter is feasible, then reading off the extremal graph from one of the three explicit families. This avoids separate case analyses for each parameter and directly yields results for the number of edges, sum of degree powers, adjacency spectral radius, and signless Laplacian spectral radius.
minor comments (3)
- §1 (abstract): the statement of result (iii) for n=2k+1 claims G ≅ K_n, but the family G³_{n,k} is only defined for n≥2k+2; a brief remark on why the complete graph is the unique maximizer in the boundary case would improve clarity.
- The notation W_{n,k,s} is introduced for the graphs in G¹_{n,k} but not reused in the statements of (ii) and (iii); consistent naming across the three families would aid readability.
- The applications section is announced as 'directly derived' from the three theorems, but no explicit list or table of corollaries (e.g., which parameters satisfy feasibility) appears in the abstract; adding a short enumerated list would strengthen the claim of unification.
Simulated Author's Rebuttal
We thank the referee for the positive assessment of our work and the recommendation for minor revision. No major comments appear in the report, so we have nothing to address point-by-point.
Circularity Check
No significant circularity; derivation is self-contained from definition
full rationale
The paper defines a feasible parameter P via two explicit monotonicity properties (non-decreasing under Kelmans operations, strictly increasing under edge addition). It then proves that any maximizer of such a P in the relevant forbidden-subgraph classes must belong to the listed families. This is a direct structural characterization from the hypothesis, not a reduction of the claim to itself by construction, fitted parameters, or self-citation chains. The abstract and results contain no load-bearing self-citations or renamings of known results as new derivations. The method unifies applications but does not create circularity in the central claims.
Axiom & Free-Parameter Ledger
axioms (1)
- standard math Standard axioms of simple undirected graphs and the definition of the Kelmans operation G_uv.
Reference graph
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