English

Graphs with core(G) = nucleus(G)

Combinatorics 2026-03-31 v1 Discrete Mathematics

Abstract

Let GG be a finite simple graph. An independent set II of GG is critical if IN(I)JN(J)\left|I\right|-\left|N(I)\right|\ge\left|J\right|-\left|N(J)\right| for every independent set JJ of GG. A critical independent set is maximum if it has maximum cardinality. The corecore and the nucleusnucleus of GG are defined as the intersection of all maximum independent sets and the intersection of all maximum critical independent sets, respectively. In 2019, Jarden, Levit, and Mandrescu posed the problem of characterizing the graphs satisfying core(G)=nucleus(G)core(G)=nucleus(G). In this paper, we provide a complete solution to this problem. Using Larson's independence decomposition, which partitions any graph into a K\"onig--Egerv\'ary component LGL_G an a 22-bicritical component LGcL_G^c, we establish that core(G)=nucleus(G)core(G)=nucleus(G) holds if and only if core(LGc)=core ({L_G^c})=\emptyset and no vertex of corona(G)corona(G) lies in the boundary between LGL_G and LGcL_G^c. We also show that the same boundary condition is equivalent to the identity diadem(G)=corona(G)L(G)diadem(G)=corona(G) \cap L(G). Several consequences and related structural properties are also derived.

Keywords

Cite

@article{arxiv.2603.27783,
  title  = {Graphs with core(G) = nucleus(G)},
  author = {Vadim E. Levit and Eugen Mandrescu and Kevin Pereyra},
  journal= {arXiv preprint arXiv:2603.27783},
  year   = {2026}
}

Comments

17 pages, 1 figure

R2 v1 2026-07-01T11:43:01.859Z