978 resultados para polycrystalline 3C-SiC
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Pie de imp. tomado de colofón
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Tit. tomado de principio de texto
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Sign. : []\p8\s, A-Z-\p8\s, Aa-Nn\p8\s, Oo\p4\s
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Sign.: [ ]1, a-c4, A-Z4, 2A-2Z4, 3A-3C4
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[calderón]8, 2[calderón]8, 3[calderón]2, A-T8, V4
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Datos tomados de Palau, II, 26555
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Sign. : A(1-4)2, A(5)12
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Sign.: [calderón]4, 2[calderón]4, A-Z4, Aa-Zz4, Aaa4
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Fecha en colofón
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Nombres de imp. constan en colofón
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Al final del texto: "el valenciano"
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Hay un ejemplar encuadernado con: "Reseña de la insurrección de Valencia, sitio, bombardeo y rendición de los sublevados" (Carreres/4436)
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The effect of the temperature on the compressive stress–strain behavior of Al/SiC nanoscale multilayers was studied by means of micropillar compression tests at 23 °C and 100 °C. The multilayers (composed of alternating layers of 60 nm in thickness of nanocrystalline Al and amorphous SiC) showed a very large hardening rate at 23 °C, which led to a flow stress of 3.1 ± 0.2 GPa at 8% strain. However, the flow stress (and the hardening rate) was reduced by 50% at 100 °C. Plastic deformation of the Al layers was the dominant deformation mechanism at both temperatures, but the Al layers were extruded out of the micropillar at 100 °C, while Al plastic flow was constrained by the SiC elastic layers at 23 °C. Finite element simulations of the micropillar compression test indicated the role played by different factors (flow stress of Al, interface strength and friction coefficient) on the mechanical behavior and were able to rationalize the differences in the stress–strain curves between 23 °C and 100 °C.
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Computational homogenization by means of the finite element analysis of a representative volume element of the microstructure is used to simulate the deformation of nanostructured Ti. The behavior of each grain is taken into account using a single crystal elasto-viscoplastic model which includes the microscopic mechanisms of plastic deformation by slip along basal, prismatic and pyramidal systems. Two different representations of the polycrystal were used. Each grain was modeled with one cubic finite element in the first one while many cubic elements were used to represent each grain in the second one, leading to a model which includes the effect of grain shape and size in a limited number of grains due to the computational cost. Both representations were used to simulate the tensile deformation of nanostructured Ti processed by ECAP-C as well as the drawing process of nanostructured Ti billets. It was found that the first representation based in one finite element per grain led to a stiffer response in tension and was not able to predict the texture evolution during drawing because the strain gradient within each grain could not be captured. On the contrary, the second representation of the polycrystal microstructure with many finite elements per grain was able to predict accurately the deformation of nanostructured Ti.
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Sign.: A4
