What question did this study set out to answer?

The aim is to prove the Colin de Verdière conjecture relating chromatic numbers and invariants in finite simple graphs.

June 2, 2026Open Access

A Topological Proof of the Colin de Verdière Conjecture via Neighborhood Complexes and Spectral Saturation

Key Points

The aim is to prove the Colin de Verdière conjecture relating chromatic numbers and invariants in finite simple graphs.
Established the relationship between chromatic number and the Colin de Verdière invariant.
Utilized neighborhood complexes and a specific weighted Laplacian derived from Schrödinger matrices.
Applied Mayer-Vietoris exact sequence and combinatorial Hodge theory for proofs.
Proved that chromatic number χ(G) is less than or equal to μ(G) + 1 for any graph G.
Demonstrated that the neighborhood complex of graphs with χ = μ + 1 has a specific connectivity.
Verified that critical edges influence the growth of μ(G) in critically saturated graphs.

Abstract

We prove the Colin de Verdière conjecture: for every finite simple graph G, the chromatic number χ(G) satisfies χ(G) ≤ μ(G) + 1, where μ(G) is the Colin de Verdière invariant. The proof uses the neighborhood complex N(G) introduced by Lovász and a novel weighted Laplacian constructed from Schrödinger matrices realizing μ(G). We show that μ(G) equals the maximum dimension of the kernel of this Laplacian, and we establish a Saturation Lemma: if a graph is critically saturated (χ = μ + 1), then adding a critical edge forces μ to grow by at least one. The argument relies on Mayer-Vietoris exact sequence and combinatorial Hodge theory to relate cohomology of N(G) to the kernel of the Laplacian. We then prove that any graph with χ = μ + 1 is topologically saturated, i.e. its neighborhood complex has connectivity exactly χ − 2. The conjecture follows by induction on χ.

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