Feshbach resonances and mesoscopic phase separation near a quantum critical point in multiband FeAs-based superconductors

TL;DR

This paper explores how Feshbach resonances near a quantum critical point in multiband FeAs superconductors enhance high-temperature superconductivity, influenced by tuning chemical potential, disorder, and lattice fluctuations.

Contribution

It demonstrates the role of Feshbach resonances in high Tc superconductivity in FeAs compounds and how tuning parameters near a quantum critical point controls the superconducting phase.

Findings

Feshbach resonance enhances superconductivity in FeAs-based materials.

Tuning chemical potential and disorder can reach a quantum critical point.

Superconducting gaps support the Feshbach resonance scenario.

Abstract

High Tc superconductivity in FeAs-based multilayers (pnictides), evading temperature decoherence effects in a quantum condensate, is assigned to a Feshbach resonance (called also shape resonance) in the exchange-like interband pairing. The resonance is switched on by tuning the chemical potential at an electronic topological transition (ETT) near a band edge, where the Fermi surface topology of one of the subbands changes from 1D to 2D topology. We show that the tuning is realized by changing i) the misfit strain between the superconducting planes and the spacers ii) the charge density and iii) the disorder. The system is at the verge of a catastrophe i.e. near a structural and magnetic phase transition associated with the stripes (analogous to the 1/8 stripe phase in cuprates) order to disorder phase transition. Fine tuning of both the chemical potential and the disorder pushes the critical temperature Ts of this phase transition to zero giving a quantum critical point. Here the quantum lattice and magnetic fluctuations promote the Feshbach resonance of the exchange-like anisotropic pairing. This superconducting phase that resists to the attacks of temperature is shown to be controlled by the interplay of the hopping energy between stripes and the quantum fluctuations. The superconducting gaps in the multiple Fermi surface spots reported by the recent ARPES experiment of D. V. Evtushinsky et al. arXiv:0809.4455 are shown to support the Feshbach scenario.