An attempt has been made to explain the formation of pores on the fnished s
urface of short-fiber-reinforced composite materials, which is brought abou
t by fiber detachment during cutting. A stress analysis of the deformation
and fracture behavior caused by the progress of the cutting edge in the mac
roscopic region at the interface between the matrix material and the fiber
is carried out using an elastoplastic finite-element method. This analysis
reveals that stress is concentrated at the interface betn een the matrix ma
terial and the fiber far from the cutting edge as a result of the contact o
f the cutting edge. It is also revealed that cutting occurs by continuance
of the microscopic fracture mechanism involving interfacial fracture betwee
n the matrix material and fiber far from the cutting edge, Analysis of the
fracture region shows that the pore depth is 0.5 which corresponds to the f
iber diameter. This is in relatively good agreement with the experimental v
alue of 0.3. Even before the cutting tool touches the fiber, tensile stress
is generated in the fiber and it is likely to produce its fracture.