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Superconductivity in Cu x Bi 2 Se 3 and its Implications for the Undoped Topological Insulator Garrett Vanacore, Sean Vig, Xiaoxiao Wang, Jiang Wang, University of Illinois at Urbana-Champaign. Structural Analysis Results. Overview. Single crystal is chemically single phase.
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Superconductivity in CuxBi2Se3 and its Implications for the Undoped Topological Insulator Garrett Vanacore, Sean Vig, Xiaoxiao Wang, Jiang Wang, University of Illinois at Urbana-Champaign Structural Analysis Results Overview • Single crystal is chemically single phase. • X-ray diffraction indicates excellent long-range crystal quality. HREM shows no signs of stacking faults, intergrowths, or amorphous regions, indicating good quality on the nanoscale, though there is no ordering of Cu in intersitial sites • It has been theorized that topological insulators (TI) could host exotic quasiparticles (anyons) that may significantly advance experimental quantum computation. • To create these anyons, superconductivity must be induced in the surface (conducting) states of the TI, though this feat has yet to be experimentally realized. • Hor et al. have observed superconductivity in copper-doped Bi2Se3, and hope this may lead to induced superconductivity in undoped Bi2Se3. Superconducting Characterization Results • Magnetic characterization showed only CuxBi2Se3 becomes superconducting above 1.8 K, no other Cu-Bi-Se system shows superconductivity. Superconductivity is achieved in the doping range 0.10<x<0.30, with optimal single crystals between x=0.12 and x=0.15 (see FIG 2). • Field cooled and zero field cooled magnetization measurements in Cu0.12Bi2Se3 show an onset of superconductivity at 3.8 K with the zero field cooled measurement reaching about 20% of full diamagnetism at 1.8 K (see FIG 3). • Given the magnetization results, resistivity measurements are performed with CuxBi2Se3 with doping parameter x=0.12 and show a superconducting transition at 3.8 K (see FIG 4) FIG 2:Magnetization of various Cu-Bi-Se systems as a function of temperature. Note only CuxBi2Se3 systems show a drop in magnetization indicating a superconducting transition. Crystal Growth and Structural Analysis Methods • CuxBi2Se3 is grown by melting Cu, Bi, and Se at 850°C, slow cooling to 650°C and quenching in cold water. • Structural properties are determined through an ensemble of X-ray powder diffraction, high resolution electron microscopy (HREM), and ultra-high vacuum low-temperature scanning tunneling microscopy. • Structural tests are pivotal for differentiating between CuxBi2Se3 (see FIG 1) and an alternate structure created by doping, Bi2-xCuxSe3. FIG 1: The crystal structure of CuxBi2Se3. Bi2Se3 is formed from double-layers of Bi2Se6 octahedra. Cu may either intercalate between Se layers - giving CuxBi2Se3 (shown below) - or substitute for Bi atoms - giving Cu-intercalated Bi2-xCuxSe3. Conclusions and Future Work • This is the first observation of superconductivity in a material that is chemically similar to a TI, and the close chemical similarity may allow it to be used to induce superconductivity in an undoped TI. • The complexity of particle states in CuxBi2Se3 is not well understood; e.g. it is not clear where Cooper pairing arises in the material. This will be a focus of future research. Superconducting Characterization • Characterization is performed on Cu-intercalcated CuxBi2Se3 for various values of the doping parameter, x, in addition to Cu-substituted Bi2-xCuxSe3 and other Cu-Bi-Se systems. • Both AC and DC magnetization is measured, the AC measurements with a proprietary Physical Property Measurement System (PPMS), the DC measurements with a superconducting quantum interference device. Resistivity is measured using a standard four-probe technique, with currents applied in the basal plane. FIG 4. Resistivity of Cu0.12Bi2Se3 measured parallel to the basal plane, showing a superconducting transition at 3.8 K. FIG 3: Zero field cooled and field cooled magnetization measurements on Cu0.12Bi2Se3 as a function of temperature. This shows a superconducting transition at 3.8 K. Acknowledgments Professor Lance Cooper, Celia Elliott, and Y.S. Hor et al. Source: Superconductivity in CuxBi2Se3 and its Implications for Pairing in the Undoped Topological Insulator, Y.S. Hor et al., Phys. Rev. Lett. 104, 057001 (2010)