Detail publikačního výsledku

Engineered magnetization and exchange stiffness in direct-write Co-Fe nanoelements

Bunyaev, SA.; Budinska, B.; Sachser, R.; Wang, Q.; Levchenko, K.; Knauer, S.; Bondarenko, AV.; Urbanek, M.; Guslienko, KY.; Chumak, AV.; Huth, M.; Kakazei, GN.; Dobrovolskiy, OV.

Originální název

Engineered magnetization and exchange stiffness in direct-write Co-Fe nanoelements

Anglický název

Engineered magnetization and exchange stiffness in direct-write Co-Fe nanoelements

Druh

Článek WoS

Originální abstrakt

Media with engineered magnetization are essential building blocks in magnonics, spintronics, and superconductivity. However, the established thin film and lithographic techniques insufficiently suit the realization of planar components with on-demand-tailored magnetization in the lateral dimension. Here, we demonstrate the engineering of the magnetic properties of CoFe-based nanodisks fabricated by the mask-less technique of focused electron beam-induced deposition (FEBID). The material composition in the nanodisks is tuned in situ via the e-beam waiting time in the FEBID process and their post-growth irradiation with Ga ions. The saturation magnetization M-s and exchange stiffness A of the disks are deduced from perpendicular spin-wave resonance measurements. The achieved M-s variation in the broad range from 720emu/cm(3) to 1430emu/cm(3) continuously bridges the gap between the M-s values of widely used magnonic materials such as Permalloy and CoFeB. The presented approach paves the way toward nanoscale 2D and 3D systems with controllable space-varied magnetic properties.

Anglický abstrakt

Media with engineered magnetization are essential building blocks in magnonics, spintronics, and superconductivity. However, the established thin film and lithographic techniques insufficiently suit the realization of planar components with on-demand-tailored magnetization in the lateral dimension. Here, we demonstrate the engineering of the magnetic properties of CoFe-based nanodisks fabricated by the mask-less technique of focused electron beam-induced deposition (FEBID). The material composition in the nanodisks is tuned in situ via the e-beam waiting time in the FEBID process and their post-growth irradiation with Ga ions. The saturation magnetization M-s and exchange stiffness A of the disks are deduced from perpendicular spin-wave resonance measurements. The achieved M-s variation in the broad range from 720emu/cm(3) to 1430emu/cm(3) continuously bridges the gap between the M-s values of widely used magnonic materials such as Permalloy and CoFeB. The presented approach paves the way toward nanoscale 2D and 3D systems with controllable space-varied magnetic properties.

Klíčová slova

BEAM-INDUCED DEPOSITION

Klíčová slova v angličtině

BEAM-INDUCED DEPOSITION

Autoři

Bunyaev, SA.; Budinska, B.; Sachser, R.; Wang, Q.; Levchenko, K.; Knauer, S.; Bondarenko, AV.; Urbanek, M.; Guslienko, KY.; Chumak, AV.; Huth, M.; Kakazei, GN.; Dobrovolskiy, OV.

Rok RIV

2021

Vydáno

11.01.2021

Nakladatel

AMER INST PHYSICS

Místo

MELVILLE

ISSN

1077-3118

Periodikum

Applied Physics Letters

Svazek

118

Číslo

2

Stát

Spojené státy americké

Strany od

022408-1

Strany do

022408-5

Strany počet

5

URL

https://aip.scitation.org/doi/10.1063/5.0036361