Your search keyword '"Pnictides and chalcogenides"' showing total 2 results

1. The Role of Yttrium Doping on the Structural and Superconducting Properties of Sm1111 and Its Comparison with Other (RE, Y)1111 (RE $$\varvec{=}$$ La, Ce, and Nd) Iron Oxypnictides.

Author

Aswathy, P., Anooja, J., Varghese, Neson, and Syamaprasad, U.

Subjects

*YTTRIUM, *DOPING agents (Chemistry), *COMPARATIVE studies, *IRON-based superconductors, *SUBSTITUTION reactions

Abstract

The role of yttrium doping on the structural and superconducting properties of SmFeAsO $$_{1-x}$$ F $$_x$$ (Sm1111) is studied in detail and is compared with other yttrium-doped RE1111 (RE-rare earth) iron oxypnictide superconductors on the basis of the existing reports. It is found that the partial substitution of lanthanides such as La, Ce, and Nd with yttrium systematically enhances $$T_\mathrm{C}$$ of the system to different levels depending on their crystal ionic radii difference with yttrium. The isovalent substitution of these lanthanides at relatively smaller yttrium ion site causes inner chemical pressure and enhances the $$T_\mathrm{C}$$ . However, yttrium doping does not seem to be beneficial for Sm1111 because of its larger ionic size. [ABSTRACT FROM AUTHOR]

Published

2015

2. Pseudogap Analysis of Normal State Transport Behavior of 11 and 1111 Fe-Based Superconductors.

Author

Pallecchi, I., Tropeano, M., Ferdeghini, C., Lamura, G., Martinelli, A., Palenzona, A., and Putti, M.

Subjects

*IRON, *SUPERCONDUCTORS, *ELECTRIC resistance, *HEAT resistant alloys, *THERMAL electromotive force

Abstract

In this paper we analyze transport data of different families of Fe-based superconductors, within a pseudogap framework. The Fe(Te, Se) samples exhibit s-shaped resistivity ρ( T) curves, while SmFeAs(O, F) ones present a departure from their high-temperature linear behavior. In either case, a characteristic temperature can be identified. These temperatures correspond to those at which abrupt changes in the temperature behavior of Hall resistance and of Seebeck coefficient occur, suggesting that they are signatures of pseudogaps opening in the density of states. The direct correlation between these characteristic temperatures and the superconducting transition temperatures suggests that the pseudogap and the superconducting state originate from the same mechanism. Scaling procedures of resistivity curves confirm such proportionality. On the other hand, excess Fe content in Fe(Te, Se) samples affects the pseudogap temperature much more strongly than the superconducting T. Finally, we find out that the pseudogap in the 1111 family is almost insensitive to disorder, as in high- T cuprates. [ABSTRACT FROM AUTHOR]

Published

2011