Navegando por Autor "Mori, T. J. A."
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Artigo Exploring the magnetization dynamics of NiFe/Pt multilayers in flexible substrates(Elsevier, 2016-09-29) Corrêa, Marcio Assolin; Dutra, Roberta; Marcondes, Tatiana Lisboa; Mori, T. J. A.; Bohn, Felipe; Sommer, R. L.We investigate the structural and magnetic properties, and the magnetization dynamics in Ni81Fe19/Pt multilayer systems grown onto rigid and flexible substrates. The structural characterization shows evidence of a superlattice behavior, while the quasi-static magnetization characterization reveal a weak magnetic anisotropy induced in the multilayers. The magnetization dynamics is investigated through the magnetoimpedance effect. We employ a theoretical approach to describe the experimental magnetoimpedance effect and verify the influence of the effective damping parameter on the magnetization dynamics. Experimental data and theoretical results are in agreement and suggest that the multilayers present high effective damping parameter. Moreover, our experiments raise an interesting issue on the possibility of achieving considerable MI% values, even for systems with weak magnetic anisotropy and high damping parameter grown onto flexible substratesArtigo Handling magnetic anisotropy and magnetoimpedance effect in flexible multilayers under external stress(Elsevier, 2016-12-15) Agra, Kennedy Leite; Bohn, Felipe; Mori, T. J. A.; Callegari, Gustavo Luiz; Dorneles, Lúcio S.; Corrêa, Marcio AssolinWe investigate the dynamic magnetic response though magnetoimpedance effect of ferromagnetic flexible NiFe/Ta and FeCuNbSiB/Ta multilayers under external stress. We explore the possibility of handling magnetic anisotropy, and consequently the magnetoimpedance effect, of magnetostrictive multilayers deposited onto flexible substrates. We quantify the sensitivity of the multilayers under external stress by calculating the ratio between impedance variations and external stress changes, and show that considerable values can be reached by tuning the magnetic field, frequency, magnetostriction constant, and external stress. The results extend possibilities of application of magnetostrictive multilayers deposited onto flexible substrates when under external stress and place them as very attractive candidates as element sensor for the development of sensitive smart touch sensors