Low-regularity well-posedness for a mixed-sign quadratic Dirac equation on N-star metric graphs

Abstract

We study the Cauchy problem for a mixed-sign quadratic Dirac equation on a noncompact N-star metric graph G, \[ i∂t ψ= Dψ- N(ψ), ψ(0)=ψ0, \] where ψ=(ψ1,ψ2) T:R× G2 and D denotes the self-adjoint Dirac-Kirchhoff operator on G. The nonlinearity acts edgewise and is given by a bilinear interaction between the positive and negative spectral parts, \[ N(ψ)= B(Π+ψ,Π-ψ), \] where Π are the spectral projections of D and B is a fixed bilinear map on C2 applied componentwise on each edge. This is a model quadratic interaction tailored to the mixed-sign Bourgain-space mechanism, rather than a general nonlinear Dirac equation on graphs. Using Bourgain-type spaces associated with the spectral resolution of D and a mixed-sign bilinear estimate on N-star graphs, we prove local well-posedness in the operator Sobolev space HDs(G) for \(s>-18\). We also establish a blow-up alternative in HDs(G) for the maximal forward lifespan.