Towards high temperature holographic superconductors

Abstract

We explore a holographic superconductor model in which a real scalar field is non-minimally coupled to a gauge field. We consider several types of the non-minimal coupling function h() including exponential, hyperbolic (cosh), power-law and fractional forms. We investigate the influences of the non-minimal coupling parameter α on condensation, critical temperature and conductivity. We can categorize our results in two groups. In the first group, conductor/superconductor phase transition is easier to occur for larger values of α, while in the second group stronger effects of the non-minimal coupling makes the formation of scalar hair harder. Although the real and imaginary parts of conductivity are impressed by different forms of h(), they follow some universal behaviors such as connecting with each other through Kramers-Kronig relation in low frequency regime or the appearance of gap frequency at low temperatures. We find the best form of forms of non-minimal coupling function that gives us better information in wide range of non-minimal coupling constant and temperature. Choosing the best form of h(), we construct a family of solutions for holographic conductor/superconductor phase transitions to discover the effect of the hyperscaling violation when the gauge and scalar fields are non-minimally coupled. we find that the critical temperature increases for higher effects of hyperscaling violation θ and non-minimal coupling constant α. By increasing these two parameters, we obtain lower values of condensation which means that conductor/superconductor phase transition will acquire easier. Furthermore, we understand that the hyperscaling violation affects the conductivity σ of the holographic superconductors and changes the expected relation in the gap frequency. Some universal behaviors like infinite DC conductivity are observed.

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