Polarizability and magnetoplasmonic properties of magnetic general nanoellipsoids

Maccaferri, Nicolò; González-Díaz, J. B.; Bonetti, Stefano; Berger, Andreas; Fontcuberta, Josep; Dijken, Sebastiaan van; Nogués, J.; Bonanni, Valentina; Pirzadeh, Zhaleh; Dmitriev, Alexandre; Åkerman, Johan; Vavassori, P.

doi:10.1364/oe.21.009875

Cited by 43 publications

(41 citation statements)

References 67 publications

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“…Comparison of the measured spectra with theoretical calculations show an outstanding agreement (see Figures 2c and 2d). The calculated spectra are obtained by computing the polarizability of an individual nickel nanoparticle (material parameters from reference [43]), taking into account the dynamic depolarization fields, as described in detail in references [38,44]. The nanostructures layer is modelled using a Maxwell-Garnett effective medium approximation (EMA) where the polarizability of the layer is calculated based on the response of the individual nanoparticles and taking into account their density.…”

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confidence: 99%

Magnetoplasmonic Design Rules for Active Magneto-Optics

et al. 2014

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Light polarization rotators and nonreciprocal optical isolators are essential building blocks in photonics technology. These macroscopic passive devices are commonly based on magneto-optical Faraday and Kerr polarization rotation. Magnetoplasmonics, the combination of magnetism and plasmonics, is a promising route to bring these devices to the nanoscale. We introduce design rules for highly tunable active magnetoplasmonic elements in which we can tailor the amplitude and sign of the Kerr response over a broad spectral range.

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Magnetoplasmonic Design Rules for Active Magneto-Optics

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“…. We calculated the diagonal polarizability tensor elements α ii = [ ϵ m ( ϵ − ϵ m )]/[ ϵ m + N ii ( ϵ − ϵ m )], where ϵ is the electric permittivity of the material of the disk, ϵ m the dielectric constant of the embedding medium and N ii is the depolarizing factor along the i ‐direction, which accounts for the finite size and shape of the disk . To reproduce the experimental extinction efficiency we considered, first, an isolated disk embedded in a medium with an index of refraction n = 1.15, to account for the disks–substrate interface.…”

Section: Methodsmentioning

confidence: 99%

“…Since now we are dealing with the field reflected by the surface of the effective medium film, the relevant phases to be considered are those of the Fresnel reflectivity coefficients r ss and r ps calculated using the TMM. These coefficients take into account the boundary conditions that the total electric and magnetic fields must fulfill at the air/film and film/air interfaces, besides including the relevant nanodisks polar-izabilities [43]. As a result, the wavelength dependences of f ss and f ps have substantially the same shape of those of f y and f z in the L-MOKE case, and of f y and f x in the P-MOKE case, as they are mainly determined by the corresponding polarizability tensor elements (compare dotted and dashed lines in Fig.…”

Section: Magneto-optical Characterizationmentioning

confidence: 99%

“…Purely ferromagnetic nanostructures have received less attention, although they provide an ideal playground for studying effects arising from the excitation of LPRs and the simultaneous presence of MO activity. Indeed, recent experimental and theoretical investigations of the MO Kerr effect in systems made of Ni nanostructures, have shown how the excitation of a LPR can act upon the phase of the reflected light and, thereby, be used to tune the light polarization through the manufacturing of the nanostructures dimension and shape .…”

Section: Introductionmentioning

confidence: 99%

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Effects of a non‐absorbing substrate on the magneto‐optical Kerr response of plasmonic ferromagnetic nanodisks

Maccaferri

Fontcuberta

Bonanni

et al. 2014

Physica Status Solidi (a)

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Magnetoplasmonics is an emerging field of intense research on materials combining magnetic and plasmonic functionalities. The novel optical and magneto‐optical (MO) properties displayed by these materials could allow the design of a new class of magnetically controllable optical nano‐devices. In this work, we investigate the effects of a non‐absorbing (insulating) substrate on the MO activity of pure ferromagnetic disk‐shaped nanostructures supporting localized plasmon resonances. We show that the red‐shift of the localized plasmon resonance, related to the modification of the localization of the electromagnetic field due to the substrate, is not the only effect that the substrate has on the MO response. We demonstrate that the reflectivity of the substrate itself plays a key role in determining the MO response of the system. We discuss why it is so and provide a description of the modeling tools suitable to take into account both effects. Understanding the role of the substrate will permit a more aware design of magnetoplasmonic nanostructured devices for future biotechnological and optoelectronic applications. Ferromagnetic nickel nanodisk in vacuum (left) and on a non‐absorbing substrate (right), illuminated by linearly polarized light. The polarization of the reflected field is changed in the first case due to a combination of intrinsic magneto‐optical properties and the nanoconfinement of the material. In the second case, the polarization of the reflected light is affected also by the presence of the substrate.

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“…In this framework, and thank to the development of simple fabrication routes for the metal nanoparticles (e.g., by colloidal chemistry based on reduction of metal salts [51]) and nanoparticle arrays (e.g., by nanosphere colloidal lithography [52][53][54][55][56]), LSPs have been found to be suitable for a wide range of applications, including subwavelength imaging and superlensing [57 -61], nanolasing [62][63][64], light trapping and concentrators [65][66][67], plasmon-enhanced optical tweezers [68][69][70] supersensitive plasmonic metamaterials sensors [71][72][73][74], improved photovoltaic devices [75] active optical elements [76,77] etc. In this framework, magnetism have emerged as a valuable route to add an extra degree of freedom to plasmonics, since it allows to actively induce significant changes in the optical response of meta-atoms either entirely [78][79][80][81][82][83][84][85]or partially [86][87][88][89][90][91] made of magnetic materials and supporting LSPs (for a detailed overview we refer the reader to the reviews by Maksymov [ 92], and Pineider and Sangregorio [ 93]). More in detail, magnetic materials possess what is called a magneto-optical (MO) activity, arising from spin-orbit coupling of electrons, resulting in a weak magnetic-field i...…”

Section: Localized Plasmons and Magneto-optics In Magnetic Meta-atomsmentioning

confidence: 99%

Coupling phenomena and collective effects in resonant meta-atoms supporting both plasmonic and (opto-)magnetic functionalities: an overview on properties and applications [Invited]

Maccaferri¹

2019

J. Opt. Soc. Am. B

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We review both the fundamental aspects and the applications of functional magneto-optic and opto-magnetic metamaterials displaying collective and coupling effects on the nanoscale, where the concepts of optics and magnetism merge to produce unconventional phenomena. The use of magnetic materials instead of the usual noble metals allows for an additional degree of freedom for the control of electromagnetic field properties, as well as it allows light to interact with the spins of the electrons and to actively manipulate the magnetic properties of such nanomaterials. In this context, we explore the concepts of near-field coupling of plasmon modes in magnetic meta-molecules, as well as the effect of excitation of surface lattice resonances in magneto-plasmonic crystals. Moreover, we discuss how these coupling effects can be exploited to artificially enhance optical magnetism in plasmonic meta-molecules and crystals. Finally, we highlight some of the present challenges and provide a perspective on future directions of the research towards photon-driven fast and efficient nanotechnologies bridging magnetism and optics beyond current limits.

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Polarizability and magnetoplasmonic properties of magnetic general nanoellipsoids

Cited by 43 publications

References 67 publications

Magnetoplasmonic Design Rules for Active Magneto-Optics

Magnetoplasmonic Design Rules for Active Magneto-Optics

Effects of a non‐absorbing substrate on the magneto‐optical Kerr response of plasmonic ferromagnetic nanodisks

Coupling phenomena and collective effects in resonant meta-atoms supporting both plasmonic and (opto-)magnetic functionalities: an overview on properties and applications [Invited]

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