Electromagnetic response in kinetic energy driven cuprate superconductors: Linear response approach

Krzyzosiak, Mateusz; Huang, Zheyu; Feng, Shiping; Gonczarek, R.

doi:10.1016/j.physc.2010.02.092

Cited by 7 publications

(25 citation statements)

References 69 publications

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“…Our result shows clearly that in low temperature, the magnetic field penetration depth Dk(T) exhibits a linear temperature dependence, however, it crosses over to a nonlinear behavior in the extremely low temperatures, in good agreement with experimental observation in nominally clean crystals of cuprate superconductors [4,[8][9][10]6,7]. In comparison with our previous discussions [20], our present results also show that the good agreement can be reached by introducing the second-nearest neighbors hopping t 0 in the nearest neighbors hopping t-J model. It should be emphasized that the present result for cuprate superconductors is much different from that in the conventional superconductors, where the characteristic feature is the existence of the isotropic energy gap D s , and then Dk(T) exhibits an exponential behavior as Dk(T) / exp(ÀD s /T).…”

Section: Doping and Temperature Dependence Of The Magnetic Field Penesupporting

confidence: 92%

“…3 (then Fig. 5), in the present t-t 0 -J model is the same as that in the t-J [20], and can be attributed to the nonlocal effects induced by the gap nodes on the Fermi surface in a pure d-wave pairing state [15][16][17][18][19]. A weak external magnetic field acts on the SC state of cuprate superconductors as a perturbation.…”

Section: Doping and Temperature Dependence Of The In-plane Superfluidsupporting

confidence: 61%

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Doping dependence of Meissner effect in cuprate superconductors

Feng

Huang

Zhao

2010

Physica C: Superconductivity

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Within the t-t'-J model, the doping dependence of the Meissner effect in cuprate superconductors is studied based on the kinetic energy driven superconducting mechanism. Following the linear response theory, it is shown that the electromagnetic response consists of two parts, the diamagnetic current and the paramagnetic current, which exactly cancels the diamagnetic term in the normal state, and then the Meissner effect is obtained for all the temperature $T\leq T_{c}$ throughout the superconducting dome. By considering the two-dimensional geometry of cuprate superconductors within the specular reflection model, the main features of the doping and temperature dependence of the local magnetic field profile, the magnetic field penetration depth, and the superfluid density observed on cuprate superconductors are well reproduced. In particular, it is shown that in analogy to the domelike shape of the doping dependent superconducting transition temperature, the maximal superfluid density occurs around the critical doping $\delta\approx 0.195$, and then decreases in both lower doped and higher doped regimes.Comment: 13 pages, 5 figure

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Section: Doping and Temperature Dependence Of The Magnetic Field Penesupporting

confidence: 92%

Section: Doping and Temperature Dependence Of The In-plane Superfluidsupporting

confidence: 61%

Doping dependence of Meissner effect in cuprate superconductors

Feng

Huang

Zhao

2010

Physica C: Superconductivity

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“…143,157 For the discussions of the doping and temperature dependence of the electromagnetic response, the t-J model (34) can be extended by including the exponential Peierls factors as 135,143,157 …”

Section: Electromagnetic Responsementioning

confidence: 99%

“…4.7. In this case, the electron current operator is obtained in terms of the electron polarization operator, which is a summation over all the particles and their positions, and can be expressed explicitly in the fermion-spin representation as 143,157 then the electron current operator 131 is obtained by evaluating the time-derivative of the polarization operator as j = ∂P/∂t = (i/ )[H, P]. In particular, in the linear response approach, this electron current operator is reduced as j = j (d) + j (p) , with the corresponding diamagnetic (d) and paramagnetic (p) components of the electron current operator that are given by 143,157 …”

Section: Linear Response Approachmentioning

confidence: 99%

Kinetic-energy-driven superconductivity in cuprate superconductors

Feng

Lan

Zhao

et al. 2015

Int. J. Mod. Phys. B

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Superconductivity in cuprate superconductors occurs upon charge-carrier doping Mott insulators, where a central question is what mechanism causes the loss of electrical resistance below the superconducting (SC) transition temperature? In this paper, we attempt to summarize the basic idea of the kinetic-energy-driven SC mechanism in the description of superconductivity in cuprate superconductors. The mechanism of the kinetic-energy-driven superconductivity is purely electronic without phonons, where the charge-carrier pairing interaction in the particle-particle channel arises directly from the kinetic energy by the exchange of spin excitations in the higher powers of the doping concentration. This kinetic-energy-driven d-wave SC-state is controlled by both the SC gap and quasiparticle coherence, which leads to that the maximal SC transition temperature occurs around the optimal doping, and then decreases in both the underdoped and overdoped regimes. In particular, the same charge-carrier interaction mediated by spin excitations that induces the SC-state in the particle-particle channel also generates the normal-state pseudogap state in the particle-hole channel. The normal-state pseudogap crossover temperature is much larger than the SC transition temperature in the underdoped and optimally doped regimes, and then monotonically decreases upon the increase of doping, eventually disappearing together with superconductivity at the end of the SC dome. This kinetic-energy-driven SC mechanism also indicates that the strong * Corresponding author. 1530009-1 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by UNIVERSITY OF CALIFORNIA @ SAN DIEGO on 08/24/15. For personal use only. S. Feng et al.electron correlation favors superconductivity, since the main ingredient is identified into a charge-carrier pairing mechanism not from the external degree of freedom such as the phonon but rather solely from the internal spin degree of freedom of the electron. The typical properties of cuprate superconductors discussed within the framework of the kinetic-energy-driven SC mechanism are also reviewed. 1530009-2 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by UNIVERSITY OF CALIFORNIA @ SAN DIEGO on 08/24/15. For personal use only. Kinetic-energy-driven superconductivity in cuprate superconductors Hole doping Temperature T N AF SC T c T* ~ ∆ PG~λ * PG NM 1530009-3 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by UNIVERSITY OF CALIFORNIA @ SAN DIEGO on 08/24/15. For personal use only. 1530009-4 Int. J. Mod. Phys. B 2015.29. Downloaded from www.worldscientific.com by UNIVERSITY OF CALIFORNIA @ SAN DIEGO on 08/24/15. For personal use only.Kinetic-energy-driven superconductivity in cuprate superconductors singlets would become charged, resulting in a SC-state. The RVB state is fundamentally different from the conventional Néel state in which the doped charge carrier can move freely among the RVB spin liquid and then a better compromise between the charge-carrier kineti...

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“…In this case, we need to impose boundary conditions for charge carriers, which can be done within the simplest specular reflection model 51,52 with a two-dimensional geometry of the SC plane. Following our previous discussions of the electromagnetic response in square-lattice superconductors 23,50 , the local magnetic field profile of triangular-lattice superconductors can be evaluated explicitly as, (34) and then the magnetic-field-penetration depth is obtained from this local-magnetic-field profile as,…”

Section: Doping Dependence Of Electromagnetic Responsementioning

confidence: 99%

Doping Dependence of Meissner Effect in Triangular-Lattice Superconductors

Qin

Kuang

et al. 2015

J Low Temp Phys

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In the spin-excitation-mediated pairing mechanism for superconductivity, the geometric frustration effects not only the spin configuration but also the superconducting-state properties. Within the framework of the kinetic-energy-driven superconducting mechanism, the doping and temperature dependence of the Meissner effect in triangular-lattice superconductors is investigated. It is shown that the magnetic-field-penetration depth exhibits an exponential temperature dependence due to the absence of the d-wave gap nodes at the Fermi surface. However, in analogy to the domelike shape of the doping dependence of the superconducting transition temperature, the superfluid density increases with increasing doping in the lower doped regime, and reaches a maximum around the critical doping, then decreases in the higher doped regime.

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Electromagnetic response in kinetic energy driven cuprate superconductors: Linear response approach

Cited by 7 publications

References 69 publications

Doping dependence of Meissner effect in cuprate superconductors

Doping dependence of Meissner effect in cuprate superconductors

Kinetic-energy-driven superconductivity in cuprate superconductors

Doping Dependence of Meissner Effect in Triangular-Lattice Superconductors

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