Topological Properties of Time Reversal Symmetric Kitaev Chain and Applications to Organic Superconductors

Abstract

We show that the pair of Majorana modes at each end of a 1D spin triplet superconductor with total Cooper pair spin Sx=0 (i.e., Deltaup,up = -Deltadown,down = p*Delta0; two uncoupled time reversed copies of the Kitaev p-wave chain) are topologically robust to perturbations such as mixing by the Sz=0 component of the order parameter (Deltaup,down=Deltadown,up), transverse hopping (in quasi-1D systems), non-magnetic disorder, and also, most importantly, to time reversal breaking perturbations such as applied Zeeman fields/magnetic impurities and the mixing by the Sy=0 component of the triplet order parameter (Deltaup,up=Deltadown,down). We show that the robustness to time reversal breaking results from a hidden chiral symmetry which places the system in the BDI topological class with an integer Z invariant. Our work has important implications for the quasi-1D organic superconductors (TMTSF)2X (X=PF6, CIO4) (Bechgaard salts) which have been proposed as triplet superconductors with equal spin pairing (Deltaup,up,Deltadown,down ≠ 0, Deltaup,down=0) in applied magnetic fields.