A method for finding critical stresses of dislocation movement

Abstract

A method is presented which makes possible the determination of the critical resolved shear stress, τ_c, for dislocation movement in a crystal. The method is based on the analysis of dislocation rosettes which are generated either by microindentation, or by precipitates of a second phase. The method does not require a knowledge of the indentation (or precipitate) stress field; it requires only information on the positions of a set of leading dislocation loops. At once one can also obtain the effective indentation stress field and, for the first time, the precipitate stress field. For illustration, the method is applied to the determination of τ_c in silicon, using both indentation and precipitate dislocation rosettes. The value of τ_c thus obtained varies from a low of 3×10⁷ dyn/cm² in oxygen‐free samples to a high of 5.5×10⁸ dyn/cm² in a sample containing ∼2×10¹⁸ atoms/cm³ of oxygen with clustering. The SiO₂ precipitate stress field in the present case was found to vary as x⁻¹, suggesting that the precipitate is probably a thin plate.