60 research outputs found

    Phase Transition Study of Superconducting Microstructures

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    The presented results are part of a feasibility study of superheated superconducting microstructure detectors. The microstructures (dots) were fabricated using thin film patterning techniques with diameters ranging from 50μ50\mum up to 500μ500\mum and thickness of 1μ1\mum. We used arrays and single dots to study the dynamics of the superheating and supercooling phase transitions in a magnetic field parallel to the dot surface. The phase transi- tions were produced by either varying the applied magnetic field strength at a constant temperature or changing the bath temperature at a constant field. Preliminary results on the dynamics of the phase transitions of arrays and single indium dots will be reported.Comment: 7pages in LaTex format, five figures available upon request by [email protected], preprint Bu-He 93/

    Nernst effect of iron pnictide and cuprate superconductors: signatures of spin density wave and stripe order

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    The Nernst effect has recently proven a sensitive probe for detecting unusual normal state properties of unconventional superconductors. In particular, it may sensitively detect Fermi surface reconstructions which are connected to a charge or spin density wave (SDW) ordered state, and even fluctuating forms of such a state. Here we summarize recent results for the Nernst effect of the iron pnictide superconductor LaO1xFxFeAs\rm LaO_{1-x}F_xFeAs, whose ground state evolves upon doping from an itinerant SDW to a superconducting state, and the cuprate superconductor La1.8xEu0.2SrxCuO4\rm La_{1.8-x}Eu_{0.2}Sr_xCuO_4 which exhibits static stripe order as a ground state competing with the superconductivity. In LaO1xFxFeAs\rm LaO_{1-x}F_xFeAs, the SDW order leads to a huge Nernst response, which allows to detect even fluctuating SDW precursors at superconducting doping levels where long range SDW order is suppressed. This is in contrast to the impact of stripe order on the normal state Nernst effect in La1.8xEu0.2SrxCuO4\rm La_{1.8-x}Eu_{0.2}Sr_xCuO_4. Here, though signatures of the stripe order are detectable in the temperature dependence of the Nernst coefficient, its overall temperature dependence is very similar to that of La2xSrxCuO4\rm La_{2-x}Sr_xCuO_4, where stripe order is absent. The anomalies which are induced by the stripe order are very subtle and the enhancement of the Nernst response due to static stripe order in La1.8xEu0.2SrxCuO4\rm La_{1.8-x}Eu_{0.2}Sr_xCuO_4 as compared to that of the pseudogap phase in La2xSrxCuO4\rm La_{2-x}Sr_xCuO_4, if any, is very small.Comment: To appear in: 'Properties and applications of thermoelectric materials - II', V. Zlatic and A. Hewson, editors, Proceedings of NATO Advanced Research Workshop, Hvar, Croatia, September 19 -25, 2011, NATO Science for Peace and Security Series B: Physics and Biophysics, (Springer Science+Business Media B.V. 2012

    Nernst Effect of stripe ordering La1.8x_{1.8-x}Eu0.2_{0.2}Srx_xCuO4_4

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    We investigate the transport properties of La1.8x_{1.8-x}Eu0.2_{0.2}Srx_xCuO4_4 (x=0.04x=0.04, 0.08, 0.125, 0.15, 0.2) with a special focus on the Nernst effect in the normal state. Various anomalous features are present in the data. For x=0.125x=0.125 and 0.15 a kink-like anomaly is present in the vicinity of the onset of charge stripe order in the LTT phase, suggestive of enhanced positive quasiparticle Nernst response in the stripe ordered phase. At higher temperature, all doping levels except x=0.2x=0.2 exhibit a further kink anomaly in the LTO phase which cannot unambiguously be related to stripe order. Moreover, a direct comparison between the Nernst coefficients of stripe ordering La1.8x_{1.8-x}Eu0.2_{0.2}Srx_xCuO4_4 and superconducting La2x_{2-x}Srx_xCuO4_4 at the doping levels x=0.125x=0.125 and x=0.15x=0.15 reveals only weak differences. Our findings make high demands on any scenario interpreting the Nernst response in hole-doped cuprates

    Thermoelectricity in Metals and Alloys

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    Size effect on phonon drag in platinum

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    High-temperature Superconductors: Transport Phenomena

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    Prospects for Peltier cooling of superconducting electronics

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