X‐ray investigation of the mechanisms of phase transformations in single crystals of ZnS, Zn x Cd 1− x S, and Zn x Mn 1− x S (II). Comparison of observed and calculated diffraction effects

The experimentally observed intensity profiles recorded from ZnS, Zn x Cd 1− x S and Zn x Mn 1− x S crystals at different stages of the 2H‐3C and 2H‐6H transformations are compared with those computed theoretically from the three parameter model in the previous paper. It is found that the 2H‐3C and 2H‐6H transformations occur by the nonrandom nucleation of deformation faults. The probability of the growth of a nucleus is much greater than that of the creation of a fresh nucleus. At least two different fault probabilities have therefore to be employed in computing the diffraction effects in each case. The transformation behaviour of Zn x Cd 1− x S and Zn x Mn 1− x S crystals is strongly influenced by variations in stoichiometry ( x ). Large values of x ( x > 0.95) favour the 2H‐3C transformation, whereas smaller values ( x ≦ 0.94) favour the formation of the 6H phase. A comparison of the calculated and observed intensity distributions indicates that in some crystals the 2H‐3C and 2H‐6H transformations occur simultaneously in different regions of the same single crystal.