Ni2MnGa(100) ferromagnetic shape memory alloy: A surface study

D'Souza, S. W. ; Nayak, J. ; Maniraj, M. ; Rai, Abhishek ; Dhaka, R. S. ; Barman, S. R. ; Schlagel, D. L. ; Lograsso, T. A. ; Chakrabarti, Aparna (2012) Ni2MnGa(100) ferromagnetic shape memory alloy: A surface study Surface Science, 606 (3-4). pp. 130-136. ISSN 0039-6028

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Official URL: http://www.sciencedirect.com/science/article/pii/S...

Related URL: http://dx.doi.org/10.1016/j.susc.2011.07.023

Abstract

Ni2MnGa(100) single crystal studied using low energy electron diffraction (LEED) and ultraviolet photoemission spectroscopy (UPS) exhibits interesting modification of the surface properties that are mainly influenced by surface composition as well as intrinsic effects. In the martensite phase, the LEED spot profiles show presence of an incommensurate modulation for the stoichiometric surface. In contrast, a commensurate modulation is observed for Mn-excess Ni-Mn-Ga surface. A pre-martensite phase is identified at the surface. Both the surface martensitic and pre-martensitic transition temperatures decrease as the Mn content increases. The UPS spectra in the austenite phase exhibit systematic change in shape as a function of surface composition that can be related to changes in the hybridization between Ni and Mn 3d states. The spectra in the martensite phase exhibit interesting modifications near the Fermi level, which has been compared to density of states calculated for a modulated structure by ab-initio density functional theory. Intrinsic surface properties dissimilar from the bulk are enhanced hysteresis width of the martensite transition and increased pre-martensitic transition temperature.

Item Type:Article
Source:Copyright of this article belongs to Elsevier Science.
Keywords:Photoemission Spectroscopy; Low Energy Electron Diffraction; Ferromagnetic Shape Memory Alloy; Density Functional Theory; Martensite Transition
ID Code:93083
Deposited On:13 Jun 2012 10:58
Last Modified:13 Jun 2012 10:58

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