Every signed planar graph is 5-choosable: A short proof and refinements

Abstract

A signed graph is a pair in which G is a finite simple graph and σ:(G)\+1,-1\ is a signature. Following Máčajová--Raspaud- Škoviera and Jin--Kang--Steffen, a proper coloring of is a map c:(G) with c(u)σ(uv)\,c(v) for every edge uv, and is signed k-choosable if such a coloring exists from any list assignment L with |L(v)| k. In a celebrated two-page note, Thomassen proved that every planar graph is 5 choosable, and Jin, Kang, and Steffen subsequently extended this to signed planar graphs. Our principal contribution is a short, self-contained, and signature-blind proof of the latter: the inductive bookkeeping inserts one factor of σ(·) uniformly into every constraint, so that with σ +1 the argument reduces verbatim to Thomassen's original. From the strengthened extension statement (thm:main) we deduce the main result (thm:JKS: 5 for every planar signed graph), the Máčajová--Raspaud--Škoviera signed Five-Color Theorem in the symmetric palette 2=\-2,-1,0,1,2\, the Switching Invariance Lemma, 3-choosability of outerplanar signed graphs, 1-defective signed 4-choosability of planar signed graphs, a sandwich inequality relating to the unsigned and positive'' choice numbers, and a polynomial-time list-coloring algorithm. Voigt's planar non-4-choosable graph and Mirzakhani's smaller variant show the bound 5 is best possible. We close with examples illustrating that negative edges genuinely refine unsigned phenomena, a comparison table situating our work in the literature, and several open problems.