Extremal problems on [a, b]-covered graphs
Pith reviewed 2026-05-08 17:37 UTC · model grok-4.3
The pith
H_{n,a} uniquely maximizes both edge count and spectral radius among all non-[a,b]-covered graphs.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Non-[a,b]-covered graphs exhibit highly complex structures, yet the extremal graphs that maximize the number of edges or the spectral radius in this class are completely characterized and coincide with the graph H_{n,a} for a ≤ b and b ≥ 2 (and the analogous statement holds for non-matching-covered graphs when a = b = 1).
What carries the argument
The minimum-degree forcing technique, which narrows possible structures of extremal non-covered graphs by examining minimum-degree conditions and combining them with spectral-structural analysis.
If this is right
- The extremal graph identified for graphs containing no [a,b]-factor remains extremal for the strictly larger family of non-[a,b]-covered graphs.
- Both the size-maximizing and spectral-radius-maximizing graphs are unique and equal to H_{n,a}.
- The results strengthen the earlier Hao-Li theorems on [a,b]-factor-free graphs by extending them to the covered-property setting.
Where Pith is reading between the lines
- The fact that the same graph is extremal suggests that the primary obstruction to being covered is already captured by the absence of factors.
- The minimum-degree forcing method may apply to other extremal problems involving graph properties whose structural descriptions are similarly intricate.
- It is natural to ask whether H_{n,a} also extremalizes additional invariants (such as the adjacency matrix energy or the number of spanning trees) within the same class.
Load-bearing premise
The minimum-degree forcing technique is sufficient to produce complete characterizations despite the complex structures of non-[a,b]-covered graphs.
What would settle it
Any non-[a,b]-covered graph on n vertices with more than binom(n-1,2) + a - 1 edges or with spectral radius strictly larger than that of H_{n,a}.
read the original abstract
A graph $G$ is $[a,b]$-covered if for each edge $e$ of $G$ there is an $[a,b]$-factor containing it. For $a=b=1$, an $[a,b]$-covered graph is a matching covered graph. The structural theory of matching covered graphs constitutes a cornerstone of modern matching theory. Determining whether a given graph is matching covered is a fundamental problem in structural graph theory. Lucchesi et al. [SIAM J. Discrete Math., 2018] showed that a connected graph $G$ is matching covered if and only if every barrier of $G$ is a stable set. In this paper, we completely characterize the extremal graphs that maximize the size or the spectral radius among all non-matching-covered graphs. For $a \leq b$ and $b \geq 2,$ Hao and Li [Electron. J. Combin., 2024] investigated the extremal problems on $[a,b]$-factor graphs: If $G$ contains no $[a,b]$-factors, then $e(G)\leq \binom{n-1}{2}+a-1$ with equality if and only if $G\cong H_{n,a},$ where $H_{n,a} = K_{a-1} \vee (K_{n-a} \cup K_1).$ Moreover, if $G$ contains no $[a,b]$-factors, then $\rho(G)\leq \rho(H_{n,a})$ with equality if and only if $G \cong H_{n,a}.$ Judging from the structral characterization, non-$[a,b]$-covered graphs exhibit highly complex structures, making the associated extremal problems significantly challenging. To overcome this, we develop a novel minimum-degree forcing technique. Combining this technique and spectral-structural analysis, we in this paper provide complete characterizations of the extremal graphs that maximize the size or the spectral radius within the set of non-$[a,b]$-covered graphs. An intriguing phenomenon revealed by our results is that $H_{n,a}$ remains both the size-extremal graph and the spectral extremal graph for this larger set of non-$[a,b]$-covered graphs. Consequently, our results strengthen the results of Hao-Li.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper claims to completely characterize the n-vertex graphs that maximize the number of edges and the spectral radius among all non-[a,b]-covered graphs. For the matching-covered case a=b=1 it uses barrier properties; for a≤b with b≥2 it introduces a minimum-degree forcing technique combined with spectral-structural analysis to show that H_{n,a} = K_{a-1} ∨ (K_{n-a} ∪ K_1) is the unique maximizer for both quantities, thereby strengthening the earlier Hao-Li bounds that applied only to graphs containing no [a,b]-factor at all.
Significance. If the characterizations are correct, the work is a meaningful extension of extremal results in matching and factor theory to the strictly larger class of non-covered graphs. The observation that the same extremal graph H_{n,a} remains unique for both the edge-maximization and spectral-radius problems is noteworthy, and the newly introduced minimum-degree forcing technique is a potentially reusable tool for other structural questions involving factors and coverings.
minor comments (3)
- [§2] §2 (Preliminaries): the notation for an [a,b]-factor and for an edge being covered by such a factor should be stated explicitly with a short example for a=2, b=3 to avoid ambiguity when the reader reaches the forcing arguments.
- [Theorem 1.3] Theorem 1.3 and its proof: the reduction from the general a≤b case to the a=b=1 case is only sketched; a short paragraph clarifying how the barrier condition lifts to the general setting would improve readability.
- [Figure 1] Figure 1: the drawing of H_{n,a} for n=7, a=3 is too small to read the partition labels; enlarging it or adding a caption that explicitly identifies the clique sizes would help.
Simulated Author's Rebuttal
We thank the referee for the careful reading and positive assessment of our manuscript. We appreciate the recognition that our results meaningfully extend extremal problems from graphs without [a,b]-factors to the larger class of non-[a,b]-covered graphs, and that the uniqueness of H_{n,a} for both the edge-maximization and spectral-radius problems is noteworthy. The referee's summary accurately describes our approach, including the barrier properties for a=b=1 and the minimum-degree forcing technique combined with spectral-structural analysis for b≥2. As the recommendation is minor revision but the major comments section contains no specific points, we provide no point-by-point rebuttals below.
Circularity Check
No significant circularity; derivation relies on independent prior characterizations plus new technique
full rationale
The paper's central results extend Hao-Li extremal bounds on non-[a,b]-factor graphs to the strictly larger class of non-[a,b]-covered graphs by introducing a minimum-degree forcing technique combined with spectral-structural analysis. This rests on the independent structural theorem of Lucchesi et al. (every barrier is stable iff matching-covered) and the Hao-Li size/spectral bounds for the factor case; neither is a self-citation, nor is any claimed extremal graph H_{n,a} obtained by fitting parameters or by renaming a prior result. The derivation chain therefore remains self-contained against external benchmarks and does not reduce any prediction to its own inputs by construction.
Axiom & Free-Parameter Ledger
axioms (2)
- standard math Finite undirected simple graphs and the standard definitions of factors, barriers, and spectral radius.
- domain assumption The barrier characterization of matching covered graphs due to Lucchesi et al. holds.
Reference graph
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