Abstract
Via both numerical and analytical methods, we build the holographic s-wave insulator/superconductor model in the five-dimensional AdS soliton with the Horndeski correction in the probe limit and study the effects of Horndeski parameter k on the superconductor model. For the fixed mass squared of the scalar field (m^2), the critical chemical potential mu _c increases with the larger Horndeski parameter k, which means that the increasing Horndeski correction hinders the superconductor phase transition. Meanwhile, above the critical chemical potential, the obvious pole arises in the low frequency of the imaginal part of conductivity, which signs the appearance of superconducting state. What is more, the energy of quasiparticle excitation decreases with the larger Horndeski correction. Furthermore, the critical exponent of the condensate (charge density) is frac{1}{2} (1), which is independent of the Horndeski correction. In addition, the analytical results agree well with the numerical results. Subsequently, the conductor/superconductor model with Horndeski correction is analytically realized in the four- and five-dimensional AdS black holes. It is observed that the increasing Horndeski correction decreases the critical temperature and thus hinders the superconductor phase transition, which agrees with the numerical result in the previous works.
Highlights
In contrast with the conventional superconductor, the high critical temperature superconductor is believed to involve strong interaction and its pair mechanism is one of the most challenges in condensed matter physics
The Meissner effect and the vortex lattice solution about the superconductor were managed to realize via the holographic duality [9], following which the numerical results about holographic superconductor model were upheld by the analytical SturmLiouville (S-L) eigenvalue method [10]
Holographic superconductor models were studied from various perspectives [11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50], which greatly promoted the development of holographic superconductor model
Summary
In contrast with the conventional superconductor, the high critical temperature superconductor is believed to involve strong interaction and its pair mechanism is one of the most challenges in condensed matter physics. We will generalized the insulator/superconductor model from the minimal coupling between the gravity and scalar field to the nonminimal case by introducing the Horndeski correction and study the effects of the Horndeski coupling parameter on the critical value as well as the conductivity. We firstly construct the holographic swave insulator/superconductor phase transition in the fivedimensional AdS soliton with the Maxwell complex scalar field coupled to the Einstein tensor (i.e., the Horndeski correction) via the numerical method. Due to the soliton’s lower energy than the one of the AdS vacuum, the soliton gravitational background corresponds to the field theory with a “mass gap”, which is similar to the insulator in the condensed physics and is believed to provide a gravitational background for modeling the holographic insulator/superconductor phase transition [29,35,68,69]. (8) restore to the standard case in Refs. [29,35,68,69]
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