Effect of nitrogen on stacking fault energy of f.c.c. iron-based alloys

On the variation of wire texture with stacking fault energy in f.c.c. metals and alloys \* Wire textures of cold-drawn f.c.c. metals and alloys are describable as some combination of (100) and \* Received &iemh 2, 1965. i To produce this twinning one must, of course, impose the necessary stresses; a

The intrinsic stacking fault energy (SFE) is a critical parameter that defines the type of plasticity mechanisms in austenitic high-Mn steels. We have performed ab initio investigations to study the effect of interstitial carbon atoms on the SFE of face-centred cubic (fcc) Fe-C alloys. Simulating th

A calculation is made on the segregation of solute atoms at stacking faults in f.o.0. crystals under equilibrium conditions. The expression given by Dorn relating the concentrations of solute atoms in the faulted and unfaulted regions is rederived. A new expression is given for the equilibrium width

## Abstract Neutronographic texture investigations are presented for nickel and Co32Ni – the representatives of f.c.c. metals of very high or extremely low relative stacking‐fault energies, resp., as well as for α‐brasses with zinc concentrations between 1 and 4 atomic percent, which are typical fo