Path-Minimality of p-Energy for Connected Graphs

Abstract

Let G be a simple connected graph on n vertices, and let λ1(G),λ2(G),…,λn(G) be the eigenvalues of its adjacency matrix A(G). For p>0, define the p-energy of G by Ep(G)=Σi=1n |λi(G)|p. We prove that, for every real number p 2 and every simple connected graph G on n vertices, Ep(G) Ep(Pn), where Pn denotes the path on n vertices. Moreover, for each fixed p>2, equality holds if and only if G Pn. Together with the previously known star-minimality results, this completes the solution of two questions of Nikiforov. The proof combines two different comparison principles. For 2<p<4, we use a bipartite reduction, a Mellin representation of fractional powers, and a determinant comparison involving matching generating polynomials and tree shifts. For p4, we prove a second-order stop-loss comparison for the squared singular values of bipartite graphs. This comparison is established by rank-one spectral-shift estimates, deletion-minimal counterexamples, and a finite certified analysis of the terminal sparse-sun configurations.