Abstract

We have earlier proposed models of preformed hole pairs based on the results of our electron paramagnetic resonance experiments. A hole doped in a cuprate superconductor causes ferromagnetic alignment of the spins of the holes of 4 Cu2+ ions of the plaquette (CuO)4 in which it enters. Spin alignments undergo oscillations from vertically upward to vertically downward of the CuO2 plane. Vertical projections of spins go on changing when they pass through different plaquettes going to zero when they pass through the CuO2 plane. Ferromagnetic alignments of spins produce magnetic fields on the plane proportional to their vertical projections. When two holes travelling in CuO2 plane come across each other at a certain distance between them, they are attracted towards each other by Heisenberg exchange interaction and their path is decided by the magnetic field produced due to spin alignments. Their path is similar to 3dx2 - y2 atomic orbital. Y-123 has been chosen as an example. Due to plethora of evidence of antiferromagnetic fluctuations in cuprates, hole-pair formation has been tried in Y-123 assuming antiferromagnetic fluctuations in it. It has been found that hole-pair formation in spite of AFM fluctuations can be explained on the same lines as done earlier. Hole-pair formation was tried in Tl-2201 to test whether the same rules apply in cuprates with very high coherence lengths. Coherence length in Tl-2201 = 52 &Aring, whereas in Y-123 = 15 20 &Aring in CuO2 plane. It has been reported that in Tl-2201 the CuO2 plane is very flat and smooth. From this it was concluded that high coherence length is the result of the smoothness of the plane. Further it was concluded that the smoothness of the CuO2 plane depends upon the nature of the near neighbors of the CuO2 plane. Near neighbors of Y-123 and Tl-2201 have been compared.

Highlights

  • In the absence of consensus regarding the mechanism of superconductivity in cuprates, people are thinking of preformed hole-pairs [1] [2] which below a certain temperature undergo Bose-Einstein condensation and cause superconductivity

  • When 2 holes wandering in the CuO2 sheet of a superconductor come across a column or row of (CuO)4 plaquettes within a certain distance, they are attracted towards each other by Heisenberrg exchange interaction and follow a path guided by the exchange interaction between them and magnetic field generated by the directions of spins of Cu2+ holes and their locations during circulation around a (CuO)4 plaquette in which they are situated at that instant

  • It was inferred from our work that an isolated (CuO)4 plaquette is equivalent to a (CuO)4 plaquette of continuous CuO2 plane with a hole inside it

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Summary

Introduction

In the absence of consensus regarding the mechanism of superconductivity in cuprates, people are thinking of preformed hole-pairs [1] [2] which below a certain temperature undergo Bose-Einstein condensation and cause superconductivity. It has been noted in [1] that modest magnetic field when it is perpendicular to CuO2 plane suppresses AFM resonance in YBa2Cu3O6.6 more significantly than when applied horizontally It suggests that the FM coupled spins of holes of 4 Cu2+ ions fluctuate vertically above and below the CuO2 plane. When 2 holes wandering in the CuO2 sheet of a superconductor come across a column or row of (CuO) plaquettes within a certain distance, they are attracted towards each other by Heisenberrg exchange interaction and follow a path guided by the exchange interaction between them and magnetic field generated by the directions of spins of Cu2+ holes and their locations during circulation around a (CuO) plaquette in which they are situated at that instant. Let it be clear that the holes wandering in the CuO2 plane due to doping will be called wandering holes and those associated with Cu2+ ions will be called Cu2+ holes

Formation of Hole-Pairs
Hole-Pair Formation in Spite of Antiferromagnetic Fluctuations
Degree of Antiferromagnetism and Ferromagnetism with Doping Level
Findings
Summary

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