Combined experimental and theoretical investigation of the premartensitic transition in Ni2MnGa

Abstract

Ultraviolet-photoemission (UPS) measurements and supporting specific-heat, thermal-expansion, resistivity and magnetic-moment measurements are reported for the magnetic shape-memory alloy Ni2MnGa over the temperature range 100K < T < 250K. All measurements detect clear signatures of the premartensitic transition (TPM 247K) and the martensitic transition (TM 196K). Temperature-dependent UPS shows a dramatic depletion of states (pseudogap) at TPM located 0.3eV below the Fermi energy. First-principles electronic structure calculations show that the peak observed at 0.3eV in the UPS spectra for T > TPM is due to the Ni-d minority-spin electrons. Below TM this peak disappears, resulting in an enhanced density of states at energies around 0.8eV. This enhancement reflects Ni-d and Mn-d electronic contributions to the majority-spin density of states and is accompanied by significant reconstruction of the Fermi surface.