Browsing by Autor "Keyffer Salas"
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Item type: Item , CONDUCTIVIDAD TÉRMICA EN SÓLIDOS A ALTAS TEMPERATURAS(2006) Freddy Fernández; Eduardo Rondón; Francy Sánchez; Keyffer Salas; Víctor J. García; J.M. BriceñoItem type: Item , Propiedades tribológicas de recubrimientos de carbono depositados por haz de electrones(2020) Freddy Fernández-Rojas; Arturo González; Carlos J. Fernández-Rojas; Keyffer Salas; Eduardo RondónEn este trabajo se produjeron películas de Carbono (C) sobre sustratos de acero D01 y acero D03. Las mismas fueron depositadas utilizando la técnica por haz de electrones empleando argón (Ar) como gas precursor y fueron caracterizadas a través de sus propiedades mecánicas y tribológicas. Se realizaron pruebas de: dureza, rugosidad y desgaste usando una punta piramidal tipo Berkovich para evaluar la dureza y una máquina tribológica de configuración pin sobre disco (pin-on-disc) para medir el desgaste. Se obtuvo la dureza de los recubrimientos, la cual varío respecto al sustrato utilizado, lo que originó un cambio en el coeficiente de fricción y desgaste. Un aumento considerable en la dureza permitió la disminución del coeficiente de fricción.Item type: Item , Thermal conductivity of solids to high temperatures(2006) Freddy Fernández; Eduardo Rondón; Francy Sánchez; Keyffer Salas; Víctor J. García; J.M. BriceñoThe search of new materials for the design of the next generation of Thermal Barriers Coating (TBC) focuses on materials with very low thermal conductivity ( ) λ to high temperatures ( D T θ ≥ where D θ is the Debye s temperature). The dependence of the thermal conductivity with the temperature can be divided in four regions. In region I, at low temperature ( ) 20 T K ≤ , the thermal conductivity is determined by the physical dimensions of the material, the size of the grain and the spacing among dislocations. The thermal conductivity in this region increased quickly with the temperature, being proportional to 3 T . In region II, the thermal conductivity reaches a maximum value, which usually happens at 20 D T θ ≈ . In the region III, the lack of harmony (anharmonic effect) of the phonons begins to be significant and the thermal conductivity diminishes with 1 T − . Finally at very high temperatures ( ) D T θ ≥ in the region IV, the thermal conductivity becomes independent of the temperature. Due to the absence of a rigorous theory that can explains the behavior of thermal conductivity in regions III and IV, in terms of the fundamental physical processes that happen, in this work we present and review the existent models to estimate the values for the thermal conductivity of materials to high temperatures. It was found that the fundamental physical process responsible for the decrease in thermal conductivity in region III is the phonons dispersion through the uprocess or «umklapp» of phonons. In region IV, the behavior of the thermal conductivity is due to phonons whose means free path is of the order of an interatomic spacing. Also, we present the requirements that should satisfy a material showing low values of thermal conductivity to high temperatures.