R.B. Kasal scite author profile

We propose a new phase of matter, an electronic phase separation transition that starts near the upper pseudogap and segregates the holes into high and low density domains. The resulting grain boundary potential favors the development of intragrain superconducting amplitudes. The zero resistivity transition arises only when the intergrain Josephson coupling EJ is of the order of the thermal energy and phase locking among the superconducting grains takes place. We show that this approach explains the pseudogap and superconducting phases in a natural way and reproduces some recent scanning tunneling microscopy data.

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The disordered induced interaction and the phase diagram of cuprates

Mello¹,

Kasal²

2012

Physica C: Superconductivity

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There are processes in nature that resemble a true force but arise due to the minimization of the local energy. The most well-known case is the exchange interaction that leads to magnetic order in some materials. We discovered a new similar process occurring in connection with an electronic phase separation transition that leads to charge inhomogeneity in cuprate superconductors. The minimization of the local free energy, described here by the Cahn-Hilliard diffusion equation, drives the charges into regions of low and high densities. This motion leads to an effective potential with two-fold effect: creation of tiny isolated regions or micrograins, and two-body attraction, which promotes local or intragrain superconducting pairing. Consequently, as in granular superconductors, the superconducting transition appears in two steps. First, with local intra-grain superconducting amplitudes and, at lower temperature, the superconducting phase or resistivity transition is attained by intergrain Josephson coupling. We show here that this approach reproduces the main features of the cuprates phase diagram, gives a clear interpretation to the pseudogap phase and yields the position dependent local density of states gap ∆( r) measured by tunnelling experiments.

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The Two Energy Scales of Tunneling Spectra of Cuprate Superconductors

Mello

Kasal

2010

J Supercond Nov Magn

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Electronic phase separation and the inhomogeneities in Bi2212

Mello

Kasal

Passos

et al. 2009

Physica B: Condensed Matter

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Simulation of Dynamic Levitation Force Taking Flux Creep Into Account

Kasal

Andrade

Sotelo

et al. 2007

IEEE Trans. Appl. Supercond.

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R.B. Kasal

Electronic phase separation transition as the origin of the superconductivity and pseudogap phase of cuprates

The disordered induced interaction and the phase diagram of cuprates

The Two Energy Scales of Tunneling Spectra of Cuprate Superconductors

Electronic phase separation and the inhomogeneities in Bi2212

Simulation of Dynamic Levitation Force Taking Flux Creep Into Account

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