Thickness dependent enhancement of the polar Kerr rotation in Co magnetoplasmonic nanostructures

Rowan-Robinson, Richard M.; Melander, Emil; Chioar, Ioan-Augustin; Caballero, Blanca; García‐Martín, Antonio; Papaioannou, Evangelos Th.; Kapaklis, Vassilios

doi:10.1063/1.5079713

Cited by 8 publications

(3 citation statements)

References 42 publications

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“…Comparison of FOM and height amongst different works from: Gamet et al, 20 Rowan-Robinson et al, 38 and Roumi and Abdi-Ghaleh 39 …”

Section: Resultsmentioning

confidence: 99%

Enhancement of the polar magneto-optical Kerr effect with plasma hybrid microstructure

Luo,

Wang

2024

Opt. Eng.

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Since the magneto-optical Kerr effect plays an important role in the technology of detecting thin film magnetism, and the current detection technology has problems such as poor magneto-optical Kerr signals as well as large frequency of change, how to enhance the Kerr response of magneto-optical materials has become an important issue in today's scientific research. A three-layer plasma hybrid microstructure covered with "L"-shaped periodic aluminum blocks aiming for Kerr response enhancement is proposed. In the near-infrared wavelength range of 0.6 to 1.1 μm, by varying the size of the opening and width of the upper aluminum film, a maximum polar magneto-optical Kerr rotation angle of 11.08 deg was obtained in a bismuth iron garnet film with thin films and accompanied by a high reflectance. The effects of different opening sizes, widths, incidence angles, magnetic field sizes, metal materials, and magneto-optical materials on the structure were also investigated. The results show that the structure can both increase the Kerr rotation angle by adjusting the magnetic field and incidence angle as well as combine different plasma metals to enhance the magneto-optical Kerr effect, which improves the universality of engineering applications. In addition, the electric field contours at the intersection of different materials are given and the physical mechanism of the enhanced polar magneto-optical Kerr rotation effect is explained. The results of this work will provide some guidance and help for the amplification of experimental measurement signals of the Kerr effect and the design of tunable magneto-optical Kerr devices.

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“…Comparison of FOM and height amongst different works from: Gamet et al, 20 Rowan-Robinson et al, 38 and Roumi and Abdi-Ghaleh 39 …”

Section: Resultsmentioning

confidence: 99%

Enhancement of the polar magneto-optical Kerr effect with plasma hybrid microstructure

Luo,

Wang

2024

Opt. Eng.

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“…By contrast, MO‒SPR elements consisting of pure ferromagnetic materials are not special in localized magneto-plasmonic systems or magneto-plasmonic crystals. For example, Ni, Fe, and Co magnetic nanoholes strongly enhance Kerr effects 5 , 30 – 32 . In the present study, we investigate how propagating SPPs affect the polar Kerr activities of single ferromagnetic metals in nonlocalized plasmonics.…”

Section: Introductionmentioning

confidence: 99%

Polarization transformation and destructive interference on subwavelength magnetic domains in magneto-plasmonic systems

Yamane

Yanase

Hasegawa

et al. 2022

Sci Rep

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We demonstrate magneto-optical (MO) polarization transformation due to surface plasmons in CoPt perpendicular magnetic films in the polar Kerr geometry. An extraordinary Kerr rotation angle (θK = ± 88.9°) that almost reaches the upper limit of polarization is produced in the attenuated total reflection (Kretschmann) configuration. P-polarized incident radiation is almost transformed upon reflection to s-polarized radiation, which may be out of phase depending on whether the magnetization of CoPt is up or down. Moreover, the reflected intensity may be drastically modulated by applying an external magnetic field. The reflectivity goes almost to zero in the demagnetized state and increases with increasing external magnetic field. This drastic optical response is attributed to the MO destructive interference produced by the subwavelength magnetic domain structure.

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“…Nanoscale magnetophotonics merges magnetism with nanophotonics, [1] combining seamlessly magneto-optical (MO) effects with surface plasmons, thus being capable of delivering ultrahigh-performance biological and chemical sensors, [2,3] active tunability in nano-optics by external magnetic fields, [1,[4][5][6][7][8][9][10][11][12] and setting a platform for ultrafast optomagnetism and spintronic [13] devices on the nanoscale. Pure ferromagnetic plasmonic systems were earlier considered unfeasible for these purposes due to the high ohmic losses associated with the transition-metal (TM) ferromagnets.…”

Section: Introductionmentioning

confidence: 99%

Direction‐Sensitive Magnetophotonic Surface Crystals

Rowan-Robinson

Hurst

Ciuciulkaite

et al. 2021

Advanced Photonics Research

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Nanometer-thin rare-earth-transition-metal (RE-TM) alloys with precisely controlled compositions and out-of-plane magnetic anisotropy are currently in the focus for ultrafast magnetophotonic applications. However, achieving lateral nanoscale dimensions, crucial for potential device downscaling, while maintaining designable optomagnetic functionality and out-of-plane magnetic anisotropy is extremely challenging. Herein, nanosized Tb 18 Co 82 ferrimagnetic alloys, having strong out-of-plane magnetic anisotropy, within a gold plasmonic nanoantenna array to design a micrometer-scale magnetophotonic crystal that exhibits abrupt and narrow magneto-optical (MO) spectral features that are both magnetic field and light incidence direction controlled are integrated. The narrow Fano-type resonance arises through the interference of the individual nanoantenna's surface plasmons and a Rayleigh anomaly of the whole nanoantenna array, in both optical and MO spectra, which are demonstrated and explained using Maxwell theory simulations. This robust magnetophotonic crystal opens the way for conceptually new high-resolution light incidence direction sensors, as well as for building blocks for plasmon-assisted all-optical magnetization switching in ferrimagnetic RE-TM alloys.

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Thickness dependent enhancement of the polar Kerr rotation in Co magnetoplasmonic nanostructures

Cited by 8 publications

References 42 publications

Enhancement of the polar magneto-optical Kerr effect with plasma hybrid microstructure

Enhancement of the polar magneto-optical Kerr effect with plasma hybrid microstructure

Polarization transformation and destructive interference on subwavelength magnetic domains in magneto-plasmonic systems

Direction‐Sensitive Magnetophotonic Surface Crystals

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