Theory of subgap interchain tunneling in quasi one-dimensional conductors

Abstract

We suggest a theory of internal coherent tunneling in the pseudogap region, when the applied voltage U is below the free electron gap 2Delta0. We address quasi 1D systems, where the gap is originated by spontaneous lattice distortions of the Incommensurate Charge Density Wave (ICDW) type. Results can be adjusted also to quasi-1D superconductors. The instanton approach allows to calculate the interchain tunneling current both in single electron (amplitude solitons, i.e. spinons) and bi-electron (phase slips) channels. Transition rates are governed by a dissipative dynamics originated by emission of gapless phase excitations in the course of the instanton process. We find that the single-electron tunneling is allowed below the nominal gap 2Delta0 down to the true pair-breaking threshold at 2Was<2Delta, where Was=2Delta/pi is the amplitude soliton energy. Most importantly, the bi-electronic tunneling stretches down to U=0 (in the 1D regime). In both cases, the threshold behavior is given by power laws J (U-Uc)beta, where the exponent beta vF/u is large as the ratio of the Fermi velocity vF and the phase one u. In the 2D or 3D ordered phases, at temperature T<Tc, the one-electron tunneling current does not vanish at the threshold Uc anymore, but saturates above it at U-Uc Tc<<Delta. Also the bi-particle channel acquires a finite threshold Uc=Wph Tc<<Delta at the energy Wph of the 2π phase soliton.