Scattering theory for Klein-Gordon equations with non-positive energy

Abstract

We study the scattering theory for charged Klein-Gordon equations: \[\arrayl (t- v(x))2φ(t,x) ε2(x, Dx)φ(t,x)=0,[2mm] φ(0, x)= f0, [2mm] -1 tφ(0, x)= f1, array. \] where: \[ε2(x, Dx)= Σ1≤ j, k≤ n(xj bj(x))Ajk(x)(xk bk(x))+ m2(x),\] describing a Klein-Gordon field minimally coupled to an external electromagnetic field described by the electric potential v(x) and magnetic potential b(x). The flow of the Klein-Gordon equation preserves the energy: \[ h[f, f]:= ∫nf1(x) f1(x)+ f0(x)ε2(x, Dx)f0(x) - f0(x) v2(x) f0(x) x. \] We consider the situation when the energy is not positive. In this case the flow cannot be written as a unitary group on a Hilbert space, and the Klein-Gordon equation may have complex eigenfrequencies. Using the theory of definitizable operators on Krein spaces and time-dependent methods, we prove the existence and completeness of wave operators, both in the short- and long-range cases. The range of the wave operators are characterized in terms of the spectral theory of the generator, as in the usual Hilbert space case.