Litcius/Paper detail

Enhancing the soft magnetic properties of FeGa with a non-magnetic underlayer for microwave applications

Adrian Acosta, Kevin Fitzell, Joseph D. Schneider, Cunzheng Dong, Zhi Yao, Yuanxun Ethan Wang, Gregory P. Carman, Nian X. Sun, Jane P. Chang

2020Applied Physics Letters21 citationsDOI

Abstract

An ultra-thin (∼2.5 nm) non-magnetic Cu underlayer was found to have a significant effect on the microstructure, magnetic softness, and magnetostriction of sputter-deposited Fe81Ga19 (FeGa) thin films. Compared to the experimental control where FeGa was deposited directly on Si without an underlayer, the presence of Cu increased the in-plane uniaxial anisotropy of FeGa and reduced the in-plane coercivity by nearly a factor of five. The effective Gilbert damping coefficient was also significantly reduced by a factor of four, between FeGa on Si and FeGa on a Cu underlayer. The FeGa films on Cu also retained a high saturation magnetostriction comparable to those without an underlayer. The enhancement of the desirable magnetic properties for microwave applications is attributed to the Cu underlayer, promoting the (110) film texture and increasing the compressive film strain. The results demonstrated that the structural control is viable to simultaneously achieve the necessary magnetic softness and magnetostriction in FeGa for integration in strain-mediated magnetoelectric and microwave devices.

Topics & Concepts

MagnetostrictionMaterials scienceCoercivityThin filmMagnetic anisotropyComposite materialSputteringMicrostructureSaturation (graph theory)AnisotropyMicrowaveFerromagnetismNuclear magnetic resonanceMagnetizationCondensed matter physicsOpticsMagnetic fieldNanotechnologyPhysicsQuantum mechanicsMathematicsCombinatoricsMagnetic Properties and ApplicationsMagnetic properties of thin filmsAcoustic Wave Resonator Technologies