Effect of magnetic field on thermal strain, thermal expansion and negative thermal expansion property in a polycrystalline Ni55Mn18Ga27 alloy.

The magnetic field effect on phase transition and thermal expansion properties were investigated in Ni 55 Mn 18 Ga 27 alloy. The results show that the alloy has an excellent isotropy, reproducibility and thermostability in thermal strain and exhibits a large negative thermal expansion (NTE) effect in the direct and reverse martensitic transformations (MTs). For the direct MT, the average linear expansion coefficient α is about −225.21 ppm/K and the corresponding temperature span is around 8.2 K. Additionally, the sensitivities of the transformation strain and peak temperatures to field are about 88.5 ppm/T and 1.31 K/T, respectively. The rates of α and temperature spans of NTE to magnetic field are about 8.88 ppm/K T and 0.82 K/T, indicating that the magnetic field can improve the NTE property of the Ni–Mn-Ga alloy. Finally, the NTE mechanism has also been discussed. Our findings are beneficial to improving the thermal expansion and NTE properties of Ni–Mn-Ga alloys. • The thermal strain of the Ni55Mn18Ga27 alloy is highly isotropic, reproducible and thermostable. • The alloy exhibits a large negative thermal expansion (NTE) effect during the martensitic transformations (MTs). • The average linear expansion coefficient α is −225.21 ppm/K for the direct MT and the rate of α to field is ∼8.88 ppm/K T. • The NTE mechanism has also been discussed. • Applying magnetic field can improve the NTE property of the Ni–Mn-Ga alloy. [ABSTRACT FROM AUTHOR]