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Mccollam, Alix
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Publications (4/4 displayed)
- 2024Collapse of metallicity and high-Tc superconductivity in the high-pressure phase of FeSe0.89S0.11citations
- 2022Fermi Surface and Mass Renormalization in the Iron-Based Superconductor YFe_{2}Ge_{2}.
- 2022Collapse of Metallicity and High-T_c Superconductivity in the High-Pressure phase of FeSe0.89S0.11
- 2018Anomalous Hall effect in Weyl semimetal half-Heusler compounds RPtBi (R = Gd and Nd)citations
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document
Collapse of Metallicity and High-T_c Superconductivity in the High-Pressure phase of FeSe0.89S0.11
Abstract
We investigate the high-pressure phase of the iron-based superconductor FeSe$_{0.89}$S$_{0.11}$ using transport and tunnel diode oscillator studies. We construct detailed pressure-temperature phase diagrams that indicate that outside of the nematic phase, the superconducting critical temperature reaches a minimum before it is quickly enhanced towards 40 K above 4 GPa. The resistivity data reveal signatures of a fan-like structure of non-Fermi liquid behaviour which could indicate the existence of a putative quantum critical point buried underneath the superconducting dome around 4.3 GPa. Further increasing the pressure, the zero-field electrical resistivity develops a non-metallic temperature dependence and the superconducting transition broadens significantly. Eventually, the system fails to reach a fully zero-resistance state despite a continuous finite superconducting transition temperature, and any remaining resistance at low temperatures becomes strongly current-dependent. Our results suggest that the high-pressure, high-$T_c$ phase of iron chalcogenides is very fragile and sensitive to uniaxial effects of the pressure medium, cell design and sample thickness which can trigger a first-order transition. These high-pressure regions could be understood assuming a real-space phase separation caused by concomitant electronic and structural instabilities.