Session D22: Focus Session: Fe-based Superconductors - Crystal Growth, Structure, and Properties of K_xFe_1-ySe Phases
2:30 PM–5:30 PM, Monday, February 27, 2012
Room: 254B
Sponsoring Units:
DMP DCOMP
Chair: Nicholas Butch, Lawrence Livermore National Laboratory
Abstract ID: BAPS.2012.MAR.D22.9
Abstract: D22.00009 : Defect Structures and nonstoichiometry in the K$_{x}$Fe$_{2-y}$Se$_{2}$ by X-ray diffraction.
4:30 PM–4:42 PM
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Abstract 
Authors:
John Claridge
(University of Liverpool)
Alexey Ganin
(University of Liverpool)
Alec McLennan
(University of Liverpool)
John Bacsa
(University of Liverpool)
Matthew Rosseinsky
(University of Liverpool)
Yasuhiro Takabayashi
(Durham University)
Kosmas Prassides
(Durham University)
The mechanisms of charge carrier density control in the iron pnictide and chalcogenide superconductors are important as small changes in composition produce metal-insulator transitions and generate superconductivity at temperatures of up to 37K in chalcogenides and 55K in pnictides. All of the reported materials are based on a square FeX (X = Se, As) layer built from edge-sharing of FeX$_{4}$ tetrahedra. Insertion of alkali metal cations between FeSe layers affords superconductivity in A$_{x}$Fe$_{2-y}$Se$_{2}$ (A = K, Rb, Cs, Tl: 0.7 $<$ x $<$ 1, 0 $<$ y $<$ 0.5) materials highlites the defect chemistry as the iron charge states close to +2 found in the other Fe-based superconductors require the creation of considerable defect concentrations on either or both iron and alkali metal sites. Ordering of the tetrahedral site vacancies in two crystals of refined compositions K$_{0.93(1)}$Fe$_{1.52(1)}$Se$_{2}$ and K$_{0.862(3)}$Fe$_{1.563(4)}$Se$_{2}$ produces a fivefold expansion of the parent ThCr$_{2}$Si$_{2}$ unit cell in the ab plane which can accommodate 20{\%} vacancies on a single site within the square FeSe layer. The iron charge state is maintained close to +2 by coupling of the level of alkali metal and iron vacancies, doping mechanisms, which can operate at both average and local structure levels will be discussed. These structures will also be considered in terms of their local ordering and with relation to other defect chalcogenide layer structures and possible phase segregation.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2012.MAR.D22.9