Litcius/Paper detail

Strongly Enhanced Superconductivity Due to Finite Energy Spin Fluctuations Induced by an Incipient Band: A FLEX Study on the Bilayer Hubbard Model with Vertical and Diagonal Interlayer Hoppings

Karin Matsumoto, Daisuke Ogura, Kazuhiko Kuroki

2020Journal of the Physical Society of Japan26 citationsDOIOpen Access PDF

Abstract

We study the spin-fluctuation-mediated $s\pm$-wave superconductivity in the bilayer Hubbard model with vertical and diagonal interlayer hoppings. As in the two-leg ladder model with diagonal hoppings, studied previously by the present authors, superconductivity is strongly enhanced when one of the bands lies just below (or touches) the Fermi level, that is, when the band is incipient. The strong enhancement of superconductivity is because large weight of the spin fluctuations lies in an appropriate energy range, whereas the low energy, pair-breaking spin fluctuations are suppressed. The optimized eigenvalue of the linearized Eliashberg equation, a measure for the strength of superconductivity, is not strongly affected by the bare width of the incipient band, but the parameter regime where superconductivity is optimized is wide when the incipient band is narrow, and in this sense, the coexistence of narrow and wide bands is favorable for superconductivity.

Topics & Concepts

Condensed matter physicsSuperconductivityPhysicsHubbard modelDiagonalBilayerSpin (aerodynamics)Measure (data warehouse)Fermi energyElectronic band structureFermi Gamma-ray Space TelescopeEnergy (signal processing)Eigenvalues and eigenvectorsPseudogapFermi levelt-J modelSigmaElectrical resistivity and conductivityHigh-temperature superconductivityQuantum mechanicsSelf-energyFermi surfacePhysics of Superconductivity and MagnetismIron-based superconductors researchOrganic and Molecular Conductors Research