The design of advanced materials requires a deep understanding of degradation and failure pro-
cesses. It is widely recognized that the macroscopic material properties depend on the features
of the microstructure. The knowledge of this link, which is the main subject of Micromechanics
[1], is of relevant technological interest, as it may enable the design of materials with specific
requirements by means of suitable manipulations of the microstructure.
Polycrystalline materials are used in many technological applications. Their microstructure is
characterized by the grains morphology, size distribution, anisotropy, crystallographic orientation,
stiffness and toughness mismatch and by the physical-chemical properties of the intergranular
interfaces. These aspects have a direct influence on the initiation and evolution of micro-damage,
which is also sensitive to the presence of micro-imperfections. Any theory trying to explain the
failure mechanisms in these materials must then accommodate a relevant number of parameters.
In this study, a novel 3D grain-boundary micro-mechanical model for the analysis of intergranular
degradation and failure in polycrystalline materials is presented. The microstructure is generated
by means of Voronoi tessellations, able to retain the main statistical features of polycrystals. The
formulation is built on a boundary integral representation of the elastic problem for the crystals,
that are modeled as 3D anisotropic elastic domains with arbitrary orientation [2]. This representa-
tion involves only mechanical variables at the grains interfaces, i.e. displacement jumps and trac-
tions, that play an important role in the micromechanics of polycrystals. The aggregate integrity
is restored by enforcing suitable intergranular conditions. The onset and evolution of intergranular
damage is modeled using an extrinsic irreversible cohesive law, able to address mixed-mode fail-
ure conditions. Upon interface failure, a non-linear frictional contact analysis is used, to address
separation, sliding or sticking between the formed micro-crack surfaces. The incremental-iterative
algorithm for tracking the micro-evolution is presented. Several numerical tests on pseudo and
fully three-dimensional microstructures are discussed. The present formulation is a promising tool
in the framework of multiscale analysis of degradation and failure in polycrystalline materials