Structural phase transition below 250 K in superconducting K$_{0.75}$Fe$_{1.75}$Se$_{2}$

(2) Beijing National Laboratory for Condensed Matter Physics; A. Ignatov (1); A. Kumar (1); Astronomy; Chinese Academy of Sciences); G. Blumberg (2) ((1) Department of Physics; Institute of Physics; K. Rabe (1); N. L. Wang (2); P. Lubik (1)

arxiv: 1209.5718 · v1 · pith:6PDXPK5Fnew · submitted 2012-09-25 · ❄️ cond-mat.supr-con

Structural phase transition below 250 K in superconducting K_(0.75)Fe_(1.75)Se₂

A. Ignatov (1) , A. Kumar (1) , P. Lubik (1) , R. H. Yuan (2) , W. T. Guo (2) , N. L. Wang (2) , K. Rabe (1) , G. Blumberg (2) ((1) Department of Physics

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Astronomy Rutgers The State University of New Jersey (2) Beijing National Laboratory for Condensed Matter Physics Institute of Physics Chinese Academy of Sciences)

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Vibrational properties of iron-chalcogenide superconductor K$_{0.75}$Fe$_{1.75}$Se$_{2}$ with $T_{c}\sim$ 30 K have been measured by Raman and optical spectroscopies over temperature range of 3-300 K. Sample undergoes \textit{I4/m} $\to $ \textit{I4} structural phase transition accompanied by loss of inversion symmetry at $T_{1}$, below 250 K, observed as appearance of new fully-symmetric Raman mode at $\sim$ 165 cm$^{-1}$. Small vibration mode anomalies are also observed at $T_{2}\sim$ 160 K. From first-principles vibrational analysis of antiferromagnetic K$_{0.8}$Fe$_{1.6}$Se$_{2}$ utilizing pseudopotentials all observed Raman and infrared modes have been assigned and the displacement patterns of the new Raman mode identified as involving predominantly the Se atoms.

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Structural phase transition below 250 K in superconducting K_(0.75)Fe_(1.75)Se₂

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