Complete martensitic transformation sequence and magnetic properties of non-stoichiometric Ni2Mn1.2Ga0.8 alloy by first-principles calculations

“…[119,120] Zelený et al [118] showed that such ferrimagnetic ordering affects the stability of two-layer nanotwins, which allow reliable predictions of the limit for Mn content in modulated phases near 0 K. On the other hand, 10M martensite with ferromagnetic alignment of all Mn atoms was found to be more stable than NM martensite in alloys with a higher Mn content. [121] To reveal the exact effect of magnetic ordering on the stability of martensitic structures, a comparison of the total energy of various magnetic ordering, for example, ferro-/ferrimagnetic, noncolinear, and paramagnetic states, is required. A proper description of paramagnetic states with randomly oriented magnetic moments is difficult to achieve in ab initio models; thus, it is often approximated by all atoms having zero magnetic moments.…”

“…Such CPA-based analyses are available for off-stoichiometric alloys, [154] as well as alloys with additional Fe, Co, Cu, [155] Al, [168] and Zn. [124] Calculations based on supercells have shown that the excess Mn atoms in the Ga sublattice prefer to be adjacent to each other, [118,121] but such configurations are hardly accessible at low temperatures due to the slow diffusion of Mn atoms. [110] In calculations, it is typically assumed that stoichiometric Ni 2 MnGa exhibits a perfect atomic order.…”

“…[ 119,120 ] Zelený et al [ 118 ] showed that such ferrimagnetic ordering affects the stability of two‐layer nanotwins, which allow reliable predictions of the limit for Mn content in modulated phases near 0 K. On the other hand, 10M martensite with ferromagnetic alignment of all Mn atoms was found to be more stable than NM martensite in alloys with a higher Mn content. [ 121 ]…”

Experimental Observations versus First‐Principles Calculations for Ni–Mn–Ga Ferromagnetic Shape Memory Alloys: A Review

“…[119,120] Zelený et al [118] showed that such ferrimagnetic ordering affects the stability of two-layer nanotwins, which allow reliable predictions of the limit for Mn content in modulated phases near 0 K. On the other hand, 10M martensite with ferromagnetic alignment of all Mn atoms was found to be more stable than NM martensite in alloys with a higher Mn content. [121] To reveal the exact effect of magnetic ordering on the stability of martensitic structures, a comparison of the total energy of various magnetic ordering, for example, ferro-/ferrimagnetic, noncolinear, and paramagnetic states, is required. A proper description of paramagnetic states with randomly oriented magnetic moments is difficult to achieve in ab initio models; thus, it is often approximated by all atoms having zero magnetic moments.…”

“…Such CPA-based analyses are available for off-stoichiometric alloys, [154] as well as alloys with additional Fe, Co, Cu, [155] Al, [168] and Zn. [124] Calculations based on supercells have shown that the excess Mn atoms in the Ga sublattice prefer to be adjacent to each other, [118,121] but such configurations are hardly accessible at low temperatures due to the slow diffusion of Mn atoms. [110] In calculations, it is typically assumed that stoichiometric Ni 2 MnGa exhibits a perfect atomic order.…”

“…[ 119,120 ] Zelený et al [ 118 ] showed that such ferrimagnetic ordering affects the stability of two‐layer nanotwins, which allow reliable predictions of the limit for Mn content in modulated phases near 0 K. On the other hand, 10M martensite with ferromagnetic alignment of all Mn atoms was found to be more stable than NM martensite in alloys with a higher Mn content. [ 121 ]…”

Experimental Observations versus First‐Principles Calculations for Ni–Mn–Ga Ferromagnetic Shape Memory Alloys: A Review

“…Li et al [ 25 , 26 ] confirmed the monoclinic commensurate structure of the 5M martensite and the monoclinic incommensurate structure of the 7M martensite from the EBSD Kikuchi diffraction patterns. The phase stability and magnetic properties of the commensurate 5M and 7M–IC were subsequently investigated by Xu et al [ 27 , 28 ] using first-principles calculations based on the experimental results of Li et al…”

Unraveling the Phase Stability and Physical Property of Modulated Martensite in Ni2Mn1.5In0.5 Alloys by First-Principles Calculations

Stability, magnetic, electronic, elastic, thermodynamic, optical, and thermoelectric properties of Co2TiSn, Co2ZrSn and Co2HfSn Heusler alloys from calculations using generalized gradient approximation techniques