Estudio Mediante Tecnicas Interferometricas de las Propiedades Tribologicas de la ZrO2 Obtenida por Proyeccion Termica

Las barreras térmicas poseen unas propiedades mecánicas y tribológicas limitadas. Los tratamientos térmicos de sintetizado pueden utilizarse como una posible solución para su mejora. En el presente trabajo se evalúa la evolución de diversas propiedades tribológicas y mecánicas, a diferentes tiempos de sinterización, a temperatura de 1.000 °C. Se observa que el sintetizado produce un aumento de la resistencia al desgaste, de la dureza y del módulo de Young. A partir de los ensayos ball-on-disk, realizados utilizando un par friccionante de ZrO2 y de acero, se han estudiado los mecanismos de desgaste dominantes para cada uno de los pares friccionantes. Se ha observado que la delaminación entre partículas y la fractura frágil durante el proceso de desgaste son los mecanismos principales que controlan el proceso. Los caminos de desgaste estudiados mediante microscopía electrónica de barrido (SEM) e interferometría de barrido de luz blanca (SWLI) han permitido cuantificar el desgaste en cada uno de los casos. A fin de poder estudiar los recubrimientos de ZrO2 mediante SEM y SWLI ha sido necesario realizar una metalización con oro para así aumentar la conductividad eléctrica y reflectividad de las muestras.

Non-thermal emission from microquasar/ISM interaction

Context. The interaction of microquasar jets with their environment can produce non-thermal radiation as in the case of extragalactic outflows impacting on their surroundings. Significant observational evidence of jet/medium interaction in galactic microquasars has been collected in the past few years, although little theoretical work has been done regarding the resulting non-thermal emission. Aims. In this work, we investigate the non-thermal emission produced in the interaction between microquasar jets and their environment, and the physical conditions for its production. Methods. We developed an analytical model based on those successfully applied to extragalactic sources. The jet is taken to be a supersonic and mildly relativistic hydrodynamical outflow. We focus on the jet/shocked medium structure in its adiabatic phase, and assume that it grows in a self-similar way. We calculate the fluxes and spectra of the radiation produced via synchrotron, inverse Compton, and relativistic bremsstrahlung processes by electrons accelerated in strong shocks. A hydrodynamical simulation is also performed to investigate further the jet interaction with the environment and check the physical parameters used in the analytical model. Results. For reasonable values of the magnetic field, and using typical values of the external matter density, the non-thermal particles could produce significant amounts of radiation at different wavelengths, although they do not cool primarily radiatively, but by adiabatic losses. The physical conditions of the analytical jet/medium interaction model are consistent with those found in the hydrodynamical simulation. Conclusions. Microquasar jet termination regions could be detectable at radio wavelengths for current instruments sensitive to ~arcminute scales. At X-ray energies, the expected luminosities are moderate, although the emitter is more compact than the radio one. The source may be detectable by XMM-Newton or Chandra, with 1-10 arcsec of angular resolution. The radiation at gamma-ray energies may be within the detection limits of the next generation of satellite and ground-based instruments.