2019-Sustainable Industrial Processing Summit
SIPS2019 Volume 3: Kobe Intl. Symp. / Science of Innovative and Sustainable Alloys and Magnets (SISAM)

Editors:F. Kongoli, M. Calin, J.M. Dubois, K. Zuzek-Rozman
Publisher:Flogen Star OUTREACH
Publication Year:2019
Pages:156 pages
ISBN:978-1-989820-02-5
ISSN:2291-1227 (Metals and Materials Processing in a Clean Environment Series)
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    Magnetic shape memory turns to nano: the crucial role of microstructure engineering

    Franca Albertini1; Milad Takhsha Ghahfarokhi1; Francesca Casoli1; Simone Fabbrici1; Lucia Nasi1; Marco Campanini2; Cesar Magen3; Gabriele Barrera4; Federica Celegato5; Paola Tiberto5;
    1IMEM-CNR, Parma, Italy; 2EMPA, Dubendorf, Switzerland; 3INSTITUTO DE NANOCIENCIA DE ARAGON, Zaragoza, Spain; 4INRIM,, Torino, Italy; 5INRIM, Torino, Italy;
    Type of Paper: Invited
    Id Paper: 264
    Topic: 42

    Abstract:

    Magnetic shape memory Heuslers are an important class of ferroic materials for next-generation remote actuation and energy conversion (i.e. solid-state cooling and energy harvesting), arising from giant multifunctional effects (e.g. thermo/magneto-mechanical, magneto/elasto-caloric) that can be driven by external stimuli (i.e magnetic field, temperature, pressure and stress) [1]. Low-dimensional materials, mainly thin films, have recently attracted much interest for their great potential in applications (e.g. microactuators, solid-state microrefrigerators, microvalves) [2]. With respect to the bulk, they offer the further possibility of tuning properties by exploiting the epitaxial growth on suitable substrates and underlayers. Patterned films and 2D nanostructures are nowadays a vast and almost unexplored field.
    This talk is focused on microstructure engineering of continuous and patterned NiMnGa thin films, and free standing nanodisks. By a thorough multiscale magnetic and structural study ,we will show that martensitic microstructure is sensitive to size confinement and can also be easily tuned by tuning growth parameters and performing suitable post-growth treatments (magnetic field, T, stress) [3, 4]. Microstructure engineering can be exploited for the optimization of the multifunctional properties. As an example, we demonstrate the possible actuation of free standing nanodisks by the combined application of temperature and magnetic fields, giving rise to areal strain (up to 5.5%) whose intensity and sign is ruled by a martensitic microstructure [5]. On the other hand, such "microstructure flexibility" makes magnetic shape memory materials a unique system, among magnetic materials, for the "magnetic flexibility"; magnetism can be easily manipulated at the different length-scales by taking advantage of martensitic microstructure and strong spin-lattice coupling.

    Keywords:

    Advanced materials; Alloys; Magnetic Materials; Nanomaterials;

    References:

    [1] M. Acet, et al., Handbook of Magnetic Materials vol. 19, Elsevier, Amsterdam, 2011.
    [2] A. Backen et al., Adv. Eng. Mat. 14,(2012) 696.
    [3] P. Ranzieri et al., Acta Mater. 61 (2013) 263.
    [4] P. Ranzieri et al., Adv. Mater. 32, (2015) 4760.
    [5] M. Campanini et al. Small 14 (2018) 1803027.

    Cite this article as:

    Albertini F, Takhsha Ghahfarokhi M, Casoli F, Fabbrici S, Nasi L, Campanini M, Magen C, Barrera G, Celegato F, Tiberto P. (2019). Magnetic shape memory turns to nano: the crucial role of microstructure engineering. In F. Kongoli, M. Calin, J.M. Dubois, K. Zuzek-Rozman (Eds.), Sustainable Industrial Processing Summit SIPS2019 Volume 3: Kobe Intl. Symp. / Science of Innovative and Sustainable Alloys and Magnets (SISAM) (pp. 135-136). Montreal, Canada: FLOGEN Star Outreach