Interacting magnetic cluster‐spin glasses and strain glasses in Ni–Mn based Heusler structured intermetallics

Abstract: Magnetic Ni–Mn based Heusler intermetallics show complex magnetic behavior in connection with martensitic transformations (see, for instance, the phase diagram of Ni–Co–Mn–Sn on the right‐hand side). The cubic austenitic phase at high temperature shows long‐range ferromagnetic order which can considerably be weakened by the appearance of competing antiferromagnetic interactions which are induced by Mn excess and chemical disorder. With decreasing temperature a martensitic/magnetostructural transformation takes… Show more

“…Figure 2 shows that the materials do not form homogeneous alloys, instead we observe a multiplicity of coexisting non-modulated (L1 0 ) and modulated (5M, 7M) intermediate martensitic structures because of chemical clustering effects in the alloys [23,24]. This also leads to multiple spin configurations.…”

“…With increasing temperature (which can be simulated using the fixed spin moment method allowing to calculate binding curves at reduced magnetization) "ferro" and "ferri" solutions move relative to each other until the "ferro" solution becomes lower in energy at the martensitic to austenitic transition. The magnetic exchange coupling constants can be obtained from ab initio calculations [24] and are plotted in Fig. 4 for the case of Mn-excess Ni 50 Mn 30 Ga 20 compared to stoichiometric Ni 2 MnGa.…”

“…Regarding the spin-spin interactions, we have used a Potts model, which allows to keep track of the various spin multiplicities such as S = 5/2 for Mn 3+ , S = 1 for Ni 2+ , S = 3/2 for Co 2+ and S = 4/2 for Cr 2+ . For details, see [22,24,29]. The structural and magnetic properties (including magnetic exchange coupling constants) have been calculated using ab initio method whereas the thermodynamic properties and MCE have been obtained from Monte Carlo simulation, using whereby the entropy change across the magnetostructural transition in an external magnetic field is obtained by integrating the specific heat (using a model Hamiltonian which consists of magnetic, elastic and magnetoelastic terms, see [42]).…”

Large magnetocaloric effects in magnetic intermetallics: First-principles and Monte Carlo studies

“…Figure 2 shows that the materials do not form homogeneous alloys, instead we observe a multiplicity of coexisting non-modulated (L1 0 ) and modulated (5M, 7M) intermediate martensitic structures because of chemical clustering effects in the alloys [23,24]. This also leads to multiple spin configurations.…”

“…With increasing temperature (which can be simulated using the fixed spin moment method allowing to calculate binding curves at reduced magnetization) "ferro" and "ferri" solutions move relative to each other until the "ferro" solution becomes lower in energy at the martensitic to austenitic transition. The magnetic exchange coupling constants can be obtained from ab initio calculations [24] and are plotted in Fig. 4 for the case of Mn-excess Ni 50 Mn 30 Ga 20 compared to stoichiometric Ni 2 MnGa.…”

“…Regarding the spin-spin interactions, we have used a Potts model, which allows to keep track of the various spin multiplicities such as S = 5/2 for Mn 3+ , S = 1 for Ni 2+ , S = 3/2 for Co 2+ and S = 4/2 for Cr 2+ . For details, see [22,24,29]. The structural and magnetic properties (including magnetic exchange coupling constants) have been calculated using ab initio method whereas the thermodynamic properties and MCE have been obtained from Monte Carlo simulation, using whereby the entropy change across the magnetostructural transition in an external magnetic field is obtained by integrating the specific heat (using a model Hamiltonian which consists of magnetic, elastic and magnetoelastic terms, see [42]).…”

Large magnetocaloric effects in magnetic intermetallics: First-principles and Monte Carlo studies

“…In order to evaluate the magnetic exchange coupling constants, magnetic moments, and equilibrium magnetic reference states in Co-and In-doped alloys, we first performed ab initio calculations for the cubic L2 1 structure with lattice parameter a 0 = 5.85 Å and the tetragonal L1 0 structure with different tetragonal ratios, c/a, assuming that the volume of the unit cell does not practically change with structural distortion. The equilibrium lattice parameter a 0 was taken from our recent ab initio calculations [66] using the Vienna ab initio simulation package (VASP). In that work, we have done equilibrium energy calculations with tetragonal distortion c/a using 16- The calculation of exchange coupling constants has been performed for "ferro" and "ferri" configurations in austenite and martensite using the SPR-KKR package [69,70], where the Heisenberg coupling constants J ij are determinated by employing Liechtenstein's method [71] and the spin-polarized scalar-relativistic mode and atomic sphere approximation (ASA).…”

Ab Initio and Monte Carlo Approaches For the Magnetocaloric Effect in Co- and In-Doped Ni-Mn-Ga Heusler Alloys

“…The value of 5.96 Å has been estimated theoretically from ab initio relaxation calculations presented in Refs. [21,22]. The equilibrium lattice constants and bulk moduli of cubic C-doped Ni 7 Co 1 Mn 6 In 2 alloy calculated for different supercells and spin configurations are listed in Table 1.…”

Magnetic states of C-doped Ni_43.75Co_6.25Mn_37.5In_12.5Heusler alloys