Low-energy spin waves as potential driving force for superconductivity in electron-doped cuprates
Abstract
In order to fully utilize the technological potential of unconventional superconductors, an enhanced understanding of the superconducting mechanism is necessary. In the best performing superconductors, the cuprates, superconductivity is intimately linked with magnetism, although the details of this remain elusive. In search of clarity in the magnetism-superconductivity relationship, we focus on the electron-doped cuprate Nd1.85Ce0.15CuO(4-delta) (NCCO). NCCO has an antiferromagnetic ground state when synthesized, and only becomes superconducting after a reductive annealing process. This makes NCCO an ideal template to study how the magnetism differs in the superconducting and non-superconducting state, while keeping the material template as constant as possible. Using neutron spectroscopy, we reveal that the as-grown crystal exhibits a large energy gap in the magnetic fluctuation spectrum. Upon annealing, defects that are introduced by the commonly employed synthesis method, are removed and the gap is significantly reduced. While the energy gap in the annealed sample is an effect of superconductivity, we argue that the gap in the as-grown sample is caused by the absence of long-wavelength spin waves. The defects in as-grown NCCO thus play the dual role of suppressing both superconductivity and low-energy spin waves, highlighting the connection between these two phenomena.