First-principles study of doping influence on twin formation in Ni-Mn-Ga nonmodulated martensite

Abstract

We investigate how chemical substitution reshapes the energetics of twin formation in non-modulated (NM) Ni-Mn-Ga martensite. Using density functional theory, we compute generalized planar fault energy (GPFE) curves for the (101)[101] shear system in stoichiometric Ni2MnGa and in a set of doped supercells containing Cu, Co, Fe, or Zn on different sublattices. The GPFE landscape is used as a microscopic descriptor of twinning behavior: the first barrier reflects intrinsic stacking-fault formation (twin nucleation), whereas subsequent barriers govern twin thickening and boundary motion. We show that the impact of dopants is strongly site dependent. Substitutions Cu→Mn, Cu→Ni, Co→Ni, and Zn→Mn lower the nucleation barrier and generally soften the GPFE profile, indicating more favorable conditions for twin formation and propagation; these cases also correlate with a reduced tetragonality c/a, which implies a smaller twinning shear and a reduced energetic cost of twin formation. In contrast, Cu→Ga, Co→Mn, Co→Ga, Fe→Ga, and Zn→Ga increase GPFE barriers and hinder twinning, even though such substitutions are often used to enhance martensite stability and raise Tm. Fe→Mn leaves barrier heights largely unchanged, while Fe→Ni produces an anomalous GPFE response indicative of unstable twin configurations. Finally, inspired by the nanotwinning characterisation of 10M/14M modulation, we link the depth of the two-layer nanotwin minimum to modulation stability. The substitutions Fe→Mn, Cu→Ni, and Zn→Mn result in a lower energy minimum compared to the structure without the double-layered twin. The other substitutions favor the twin-free NM structure.

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