Effect of Magnetic Field and Hydrostatic Pressure on Metamagnetic Isostructural Phase Transition and Multicaloric Response of Fe<sub>49</sub>Rh<sub>51</sub> Alloy
Alexander P. Kamantsev,
Abdulkarim A. Amirov,
Vladislav D. Zaporozhets,
Igor F. Gribanov,
Aleksay V. Golovchan,
Victor I. Valkov,
Oksana O. Pavlukhina,
Vladimir V. Sokolovskiy,
Vasiliy D. Buchelnikov,
Akhmed M. Aliev,
Victor V. Koledov
Affiliations
Alexander P. Kamantsev
Kotelnikov Institute of Radioengineering and Electronics of Russian Academy of Sciences, 125009 Moscow, Russia
Abdulkarim A. Amirov
Amirkhanov Institute of Physics, Dagestan Scientific Center of Russian Academy of Sciences, 367003 Makhachkala, Russia
Vladislav D. Zaporozhets
Galkin Donetsk Institute for Physics and Engineering, 283050 Donetsk, Russia
Igor F. Gribanov
Galkin Donetsk Institute for Physics and Engineering, 283050 Donetsk, Russia
Aleksay V. Golovchan
Galkin Donetsk Institute for Physics and Engineering, 283050 Donetsk, Russia
Victor I. Valkov
Galkin Donetsk Institute for Physics and Engineering, 283050 Donetsk, Russia
Oksana O. Pavlukhina
Department of Condensed Matter Physics, Chelyabinsk State University, 454001 Chelyabinsk, Russia
Vladimir V. Sokolovskiy
Department of Condensed Matter Physics, Chelyabinsk State University, 454001 Chelyabinsk, Russia
Vasiliy D. Buchelnikov
Department of Condensed Matter Physics, Chelyabinsk State University, 454001 Chelyabinsk, Russia
Akhmed M. Aliev
Amirkhanov Institute of Physics, Dagestan Scientific Center of Russian Academy of Sciences, 367003 Makhachkala, Russia
Victor V. Koledov
Kotelnikov Institute of Radioengineering and Electronics of Russian Academy of Sciences, 125009 Moscow, Russia
The effect of a high magnetic field up to 12 T and a high hydrostatic pressure up to 12 kbar on the stability of the metamagnetic isostructural phase transition and the multicaloric effect of Fe49Rh51 alloy has been studied. The phase transition temperature shifts under the magnetic field and the hydrostatic pressure on with the rates of dTm/μ0dH = −9.2 K/T and dTm/dP = 3.4 K/kbar, respectively. The magnetocaloric and multicaloric (under two external fields) effects were studied via indirect method using Maxwell relations. The maximum of the entropy change is increasing toward the high temperature region from ∆S~2.5 J/(kg K) at 305 K to ∆S~2.7 J/(kg K) at 344 K under simultaneously applied magnetic field of 0.97 T and hydrostatic pressure of 12 kbar. The obtained results were explained using the first-principle calculations of Gibbs energies and the phonon spectra of the ferromagnetic and the antiferromagnetic phases. Taking into account the low concentration of antisite defects in the calculation cells allows us to reproduce the experimental dTm/dP coefficient.
