Abstract
One of the major puzzles regarding unconventional superconductivity is how some of the most interesting superconductors are related to an insulating phase that lies in close proximity. Here we report scanning tunneling microscopy studies of the local electronic structure of Cu doped NaFeAs across the superconductor to insulator transition. We find that in the highly insulating regime the electronic spectrum develops an energy gap with diminishing density of state at the Fermi level. The overall lineshape and strong spatial variations of the spectra are strikingly similar to that of lightly doped cuprates close to the parent Mott insulator. We propose that the suppression of itinerant electron state and strong impurity potential induced by Cu dopants lead to this insulating iron pnictide.
Highlights
A key task in unraveling the mystery of unconventional superconductivity is to disentangle the various phases that lie in close proximity to the superconducting (SC) phase
One of the major puzzles regarding unconventional superconductivity is how some of the most interesting superconductors are related to an insulating phase that lies in close proximity
We propose that the suppression of the itinerant electron states and the strong impurity potential induced by Cu dopants lead to this insulating iron pnictide
Summary
A key task in unraveling the mystery of unconventional superconductivity is to disentangle the various phases that lie in close proximity to the superconducting (SC) phase. Strong Similarities between the Local Electronic Structure of Insulating Iron Pnictide and Lightly Doped Cuprate We report scanning tunneling microscopy studies of the local electronic structure of Cu-doped NaFeAs across the superconductor-to-insulator transition.
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