1D Dirac operators with special periodic potentials

Abstract

For 1D Dirac operators Ly= i J y' + v y, where J is a diagonal 2x2 matrix with entrees 1,-1 and v(x) is an off-diagonal matrix with L2 [0,π]-entrees P(x), Q(x) we characterize the class X of pi-periodic potentials v such that: (i) the smoothness of potentials v is determined only by the rate of decay of related spectral gaps gamma (n) = | λ (n,+) - λ (n,-)|, where λ (..) are the eigenvalues of L=L(v) considered on [0,π] with periodic (for even n) or antiperiodic (for odd n) boundary conditions (bc); (ii) there is a Riesz basis which consists of periodic (or antiperiodic) eigenfunctions and (at most finitely many) associated functions. In particular, X contains symmetric potentials Xsym (Q =P), skew-symmetric potentials Xskew-sym (Q =-P), or more generally the families Xt defined for real nonzero t by Q =t P. Finite-zone potentials belonging to Xt are dense in Xt. Another example: if P(x)=a exp(2ix)+b exp(-2ix), Q(x)=Aexp(2ix)+Bexp(-2ix) with complex a, b, A, B ≠ 0, then the system of root functions of L consists eventually of eigenfunctions. For antiperiodic bc this system is a Riesz basis if |aA|=|bB| (then v ∈ X), and it is not a basis if |aA| ≠ |bB|. For periodic bc the system of root functions is a Riesz basis (and v ∈ X) always.