Effect of hydrostatic pressure on flow and deformation in highly reinforced particulate composites

Infiltrated particle reinforced composites combine a dense matrix with particles that are in mutual contact and can therefore transfer compressive stress directly from one particle to the next. As a result, these composites may combine characteristics of the plasticity of their matrix with those of granular matter plasticity. We measure here the influence of a 200 MPa superimposed fluid hydrostatic pressure on the flow stress of high volume fraction (56-62 vol pct) particulate Al2O3-Al composites produced by infiltration and show that the yield response of such composites is indeed pressure-sensitive. A simple analysis that transposes to metal matrix composites the theory of fluid-saturated granular media mechanics explains the phenomenon quantitatively. (C) 2016 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Effect of hydrostatic pressure on flow and deformation in highly reinforced particulate composites

Surface energy contributions to the work of infiltration in metal matrix composite processing

Probing the micromechanical strength of oxide ceramic composite reinforcements

Capillarity in pressure infiltration: influence of percolation and wetting angle

Surface energy contributions to the work of infiltration in metal matrix composite processing

Probing the micromechanical strength of oxide ceramic composite reinforcements

Capillarity in pressure infiltration: influence of percolation and wetting angle