RESUMEN
Plasmon polaritons, or plasmons, are coupled oscillations of electrons and electromagnetic fields that can confine the latter into deeply subwavelength scales, enabling novel polaritonic devices. While plasmons have been extensively studied in normal metals or semimetals, they remain largely unexplored in correlated materials. In this paper, we report infrared (IR) nano-imaging of thin flakes of CsV3Sb5, a prototypical layered Kagome metal. We observe propagating plasmon waves in real-space with wavelengths tunable by the flake thickness. From their frequency-momentum dispersion, we infer the out-of-plane dielectric function ϵ c that is generally difficult to obtain in conventional far-field optics, and elucidate signatures of electronic correlations when compared to density functional theory (DFT). We propose correlation effects might have switched the real part of ϵ c from negative to positive values over a wide range of middle-IR frequencies, transforming the surface plasmons into hyperbolic bulk plasmons, and have dramatically suppressed their dissipation.
RESUMEN
The recently discovered kagome superconductors AV3Sb5 (A = K, Rb, Cs) exhibit unusual charge-density-wave (CDW) orders with time-reversal and rotational symmetry breaking. One of the most crucial unresolved issues is identifying the symmetry of the superconductivity that develops inside the CDW phase. Theory predicts a variety of unconventional superconducting symmetries with sign-changing and chiral order parameters. Experimentally, however, superconducting phase information in AV3Sb5 is still lacking. Here we report the impurity effects in CsV3Sb5 using electron irradiation as a phase-sensitive probe of superconductivity. Our magnetic penetration depth measurements reveal that with increasing impurities, an anisotropic fully-gapped state changes to an isotropic full-gap state without passing through a nodal state. Furthermore, transport measurements under pressure show that the double superconducting dome in the pressure-temperature phase diagram survives against sufficient impurities. These results support that CsV3Sb5 is a non-chiral, anisotropic s-wave superconductor with no sign change both at ambient and under pressure.
RESUMEN
The magnetic ground state of the pyrochlore Yb2GaSbO7 has remained an enigma for nearly a decade. The persistent spin fluctuations observed by muon spin relaxation measurements at low temperatures have not been adequately explained for this material using existing theories for quantum magnetism. Here we report on the synthesis and characterisation of Yb2GaSbO7 to elucidate the central physics at play. Through DC and AC magnetic susceptibility, heat capacity, and neutron scattering experiments, we observe evidence for a dynamical ground state that makes Yb2GaSbO7 a promising candidate for disorder-induced spin-liquid or spin-singlet behaviour. This state is quite fragile, being tuned to a splayed ferromagnet in a modest magnetic field µ0Hcâ¼1.5T.
RESUMEN
Resumen Se presenta la síntesis de compósitos de hidroxiapatita/zirconia (HAp/ZrO2-8Y2O3) por el método de mezclado líquido en base al método de Pechini, cuya innovación radica en la obtención simultánea de ambas fases con distribución uniforme, aunque tiene la limitante de la interacción de los cationes, propiciando la formación de fases secundarias si no se controlan las variables. Los materiales fueron conformados en discos de 1 cm de diámetro y tratados a 1400 °C, para caracterizarse por espectrometría de infrarrojo (FTIR-ATR) y difracción de rayos X (DRX). Las pruebas de bioactividad fueron realizadas mediante el método de inmersión en fluidos fisiológicos simulados durante 21 días y caracterizadas por microscopia electrónica de barrido (MEB) y espectrometría de fotoelectrones emitidos por rayos X (XPS). Las pruebas de hemólisis se basaron en la norma ASTM F 756-00. Después de la inmersión, se observó la presencia de cristales de hidroxiapatita sobre la superficie del compósito, además los análisis de XPS muestran señales de energía para los elementos de calcio y fósforo. En cuanto a las pruebas de hemólisis se observaron grados de citotoxicidad por debajo del 3% con lo cual se infiere que son hemocompatibles, aunque se requieren más estudios de biocompatibilidad para su aplicación biomédica.
Abstract The synthesis of hydroxyapatite/zirconia composites (HAp/ZrO2-8Y2O3) is presented, using the liquid mixing method based on the Pechini method, whose innovation lies in the simultaneous synthesis of both phases with uniform distribution, although it has the limitation of the cations interactions, favoring the formation of secondary phases if the variables are not controlled. The obtained materials were formed into discs of 1 cm in diameter and treated at 1400 °C, and then characterized by infrared spectrometry (FTIR-ATR) and X-ray diffraction (XRD). The bioactivity tests were carried by the immersion method in simulated body fluid for 21 days and characterized by scanning electron microscopy (SEM) and X-ray photoelectron spectrometry (XPS). The hemolysis tests were based on the ASTM F 756-00 standard. After the immersion, the presence of hydroxyapatite crystals on the surface of the composite was observed; in addition, the XPS analyzes show energy signals for the elements of calcium and phosphorus. Regarding the hemolysis tests, degrees of cytotoxicity were observed below 3%, it is inferred that they are hemocompatible, although more biocompatibility studies are required for biomedical application.