Nonlocal analysis of edge-cracked nanobeams under Mode I and Mixed-Mode (I plus II) static loading

In the present paper, the behavior of an edge-cracked nanobeam under both Mode I and Mixed-Mode (I + II) static bending loading is analyzed by using the stress-driven nonlocal model (SDM), being the SDM applied for the first time in the case of Mixed-Mode loading. More precisely, the cracked nanobeam is modeled by using a modification of the classical cracked-beam theory, consisting in dividing the beam into two beam segments connected through a massless elastic rotational spring located at the cracked cross section. The bending stiffness of the cracked cross section is computed by exploiting: the Griffith energy criterion and the conventional linear elastic fracture mechanics. Cracks under both Mode I and Mixed-Mode (I + II) loading are considered. Finally, an edge-cracked cantilever nanobeam subjected to a transversal point load at the free end is analyzed. The static deflection is calculated and discussed for different values of relative crack depth, crack location, and crack orientation.

Automated summary

In this paper, the behavior of an edge-cracked nanobeam under both Mode I and Mixed-Mode (I + II) static bending loading is analyzed using the stress-driven nonlocal model (SDM), which is applied for the first time in the case of Mixed-Mode loading. The cracked nanobeam is modeled by dividing it into two beam segments connected through a massless elastic rotational spring located at the cracked cross section. The bending stiffness of the cracked cross section is computed using the Griffith energy criterion and the conventional linear elastic fracture mechanics, considering cracks under both Mode I and Mixed-Mode loading. Finally, an edge-cracked cantilever nanobeam subjected to a transversal point load at the free end is analyzed, and the static deflection is calculated and discussed for different crack parameters.