A Simple Holographic Superconductor with Momentum Relaxation

Abstract

We study a holographic superconductor model with momentum relaxation due to massless scalar fields linear to spatial coordinates(I = β δIi xi), where β is the strength of momentum relaxation. In addition to the original superconductor induced by the chemical potential(μ) at β=0, there exists a new type of superconductor induced by β even at μ=0. It may imply a new `pairing' mechanism of particles and antiparticles interacting with β, which may be interpreted as `impurity'. Two parameters μ and β compete in forming a superconducting phase. As a result, the critical temperature behaves differently depending on β/μ. It decreases when β/μ is small and increases when β/μ is large, which is a novel feature compared to other models. After analysing ground states and phase diagrams for various β/μ, we study optical electric(σ), thermoelectric(α), and thermal() conductivities. When the system undergoes a phase transition from a normal to a superconducting phase, 1/ω pole appears in the imaginary part of the electric conductivity, implying infinite DC conductivity. If β/μ <1, at small ω, a two-fluid model with an imaginary 1/ω pole and the Drude peak works for σ, α, and , but if β/μ >1 a non-Drude peak replaces the Drude peak. It is consistent with the coherent/incoherent metal transition in its metal phase. The Ferrell-Glover-Tinkham (FGT) sum rule is satisfied for all cases even when μ=0.