Relation between superconducting properties and structural features of cuprate superconductors

A new series of barium-free 1212-type superconducting mercury-based cuprates involving iron, (Hg 1Ày Fe y )Sr 2 -(Y 1Àx Ca x )Cu 2 O 7Àd (y = 0.5; 0.0 6 x 6 1.0), has been synthesized through the citrate-gel process and the sealed quartz tube method. Their lattice parameters, electrical resistivity,

The oxyfluoride phases \(x \mathrm{NbFeO}_{4}-(1-x) \mathrm{FeF}_{2}\) have been synthesized. They exist in a limited range \(0.8<x<1\). They are isomorphous with \(\mathrm{NbFeO}_{4}\), having the wolframite structure. The refinement of the crystallographic structure of the oxyfluoride phase \(\mat

From Li well-solvating solvents or complex ligands such as THF, [12]crown-4, amines etc., lithium cuprates R 2 CuLi( . LiX) crystallise in a solvent-separated ion pair (SSIP) structural type (e.g. 10). In contrast, solvents with little donor qualities for Li such as diethyl ether or dimethyl sulfide

## Abstract Y—Ba—Cu—O superconductors with a transition temperature of above 90 K are synthesized without the necessity of any thermal treatment under oxygen from mixtures of Y~2~O~3~, BaCO~3~, and CuO at a nominal composition of YBaCu~2~O~x~ (900—1000 °C, 20 h).

i]ae recently discovered homologous series HgBa~Ca,.,Cu, O2,+2+~ includes the highest superconducting transition temperature known. The preparation of thcse materials provides a continuing challenge to the synthetic solid-state chemist; pure or nearly pure samples are still proving elusive. We have