Field-controlled ultrafast magnetization dynamics in two-dimensional nanoscale ferromagnetic antidot arrays

De, Anulekha; Mondal, Sucheta; Sahoo, Swaroop; Barman, Saswati; Otani, Y.; Mitra, Rajib Kumar; Barman, Anjan

doi:10.3762/bjnano.9.104

Cited by 11 publications

(9 citation statements)

References 41 publications

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“…Bragg diffraction of SW from ADL and ensuing MBG 116 , high-symmetry magnonic modes in perpendicularly magnetized ADL 117 , and complete MBG for magnetostatic forward volume waves in 2D ADL 118 . Subsequently external and internal control of SW modes in ADL started by varying lattice constant 119 , antidot shape 120 , lattice symmetry 121 , base material 122,123 , bias field strength and orientation 114,124 . Furthermore, several interesting phenomena such as mode conversion 125 , mode crossover and mode hopping 126 , mode softening 127 , as well as the formation of magnonic mini band 128 have been reported.…”

Section: Magnetic Antidotsmentioning

confidence: 99%

Magnetization dynamics of nanoscale magnetic materials: A perspective

Barman

Mondal

Sahoo

et al. 2020

Journal of Applied Physics

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Nanomagnets form the building blocks for a gamut of miniaturized energyefficient devices including data storage, memory, wave-based computing, sensors and biomedical devices. They also offer a span of exotic phenomena and stern challenges. The rapid advancements of nanofabrication, characterization and numerical simulations during last two decades have made it possible to explore a plethora of science and technology related to nanomagnet dynamics. The progress in the magnetization dynamics of single nanomagnets and one-and two-dimensional arrays of nanostructures in the form of dots, antidots, nanoparticles, binary and bicomponent structures and patterned multilayers have been presented in details.Progress in unconventional and new structures like artificial spin ice and three-dimensional nanomagnets and spin textures like domain walls, vortex and skyrmions have been presented. Furthermore, a huge variety of new topics in the magnetization dynamics of magnetic nanostructures are rapidly emerging. An overview of the steadily evolving topics like spatiotemporal imaging of fast dynamics of nanostructures, dynamics of spin textures, artificial spin ice have been discussed. In addition, dynamics of contemporary and newly transpired magnetic architectures such as nanomagnet arrays with complex basis and symmetry, magnonic quasicrystals, fractals, defect structures, novel three-dimensional structures have been introduced. Effects of various spin-orbit coupling and ensuing spin textures as well as quantum hybrid systems comprising of magnon-photon, magnon-phonon and magnon-magnon coupling, antiferromagnetic nanostructures are rapidly growing and are expected to dominate this research field in the coming years. Finally, associated topics like nutation dynamics and nanomagnet antenna are briefly discussed. Despite showing a great progress, only a small fraction of nanomagnetism and its ancillary topics have been explored so far and huge efforts are envisaged in this evergrowing research area in the generations to come.

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Section: Magnetic Antidotsmentioning

confidence: 99%

Magnetization dynamics of nanoscale magnetic materials: A perspective

Barman

Mondal

Sahoo

et al. 2020

Journal of Applied Physics

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“…In addition, there are few reports on antidot arrays with the anisotropic structures like triangular and diamond shaped holes which may significantly modify the internal field distribution in the vicinity of the holes leading to further modifications of the SW spectra of such systems. [16,31,32] In this present work we have chosen Co 2 Fe 0.4 Mn 0.6 Si (CFMS) thin films and their antidot arrays for the investigation of SW dynamics. To the best of our knowledge, there are no reports yet for the study of magnetization dynamics in antidot arrays of similar materials.…”

Section: Introductionmentioning

confidence: 99%

“…steeper dispersion). [16,17] The edges of the holes in the antidot arrays quantize the SW modes and modulate internal magnetic field periodically due to the demagnetizing effect. [16] Over the last decade several works have been reported on the control of SW dynamics in MAL arrays by varying the antidot architecture.…”

Section: Introductionmentioning

confidence: 99%

“…[16,17] The edges of the holes in the antidot arrays quantize the SW modes and modulate internal magnetic field periodically due to the demagnetizing effect. [16] Over the last decade several works have been reported on the control of SW dynamics in MAL arrays by varying the antidot architecture. [18][19][20][21][22][23][24] Further the most desired characteristics of a material for magnonic based applications are low magnetic damping, high saturation magnetization, high curie temperature, long spin wave propagation distance, etc.…”

Section: Introductionmentioning

confidence: 99%

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Tunability of Domain Structure and Magnonic Spectra in Antidot Arrays of Heusler Alloy

et al. 2019

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Materials suitable for magnonic crystals demand low magnetic damping and long spin wave (SW) propagation distance. In this context Co based Heusler compounds are ideal candidates for magnonic based applications. In this work, antidot arrays (with different shapes) of epitaxial Co2Fe0.4Mn0.6Si (CFMS) Heusler alloy thin films have been prepared using e-beam lithography and sputtering technique. Magneto-optic Kerr effect and ferromagnetic resonance analysis have confirmed the presence of dominant cubic and moderate uniaxial magnetic anisotropies in the thin films. Domain imaging via x-ray photoemission electron microscopy on the antidot arrays reveals chain like switching or correlated bigger domains for different shape of the antidots. Time-resolved MOKE microscopy has been performed to study the precessional dynamics and magnonic modes of the antidots with different shapes. We show that the optically induced spin-wave spectra in such antidot arrays can be tuned by changing the shape of the holes. The variation in internal field profiles, pinning energy barrier, and anisotropy modifies the spin-wave spectra dramatically within the antidot arrays with different shapes. We further show that by combining the magnetocrystalline anisotropy with the shape anisotropy, an extra degree of freedom can be achieved to control the magnonic modes in such antidot lattices. arXiv:1907.02746v1 [cond-mat.mtrl-sci]

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“…Magnetic antidots, magnetic thin films with periodic arrays of holes, are currently an important topic for both the fundamental understanding of low-dimensional magnetism and a broad range of applications, such as a new generation of electronic devices [ 1 ], sensors [ 2 ], ultra-high density recording media – due to the absence of the superparamagnetic limit as there are no isolated magnetic islands – [ 3 ], and magnonics and spintronic devices [ 4 – 5 ]. The presence of the ordered non-magnetic holes induces a demagnetization field distribution that changes the magnetization switching mechanisms [ 6 ], acting as pinning centers for domain walls [ 7 ], enhancing coercivity compared to that of the continuous film [ 8 – 12 ], and affecting the magnetic properties of the film [ 13 – 19 ].…”

Section: Introductionmentioning

confidence: 99%

Magnetic properties of Fe₃O₄ antidot arrays synthesized by AFIR: atomic layer deposition, focused ion beam and thermal reduction

Palma¹,

Pereira²,

Álvaro³

et al. 2018

Beilstein J. Nanotechnol.

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Magnetic films of magnetite (Fe3O4) with controlled defects, so-called antidot arrays, were synthesized by a new technique called AFIR. AFIR consists of the deposition of a thin film by atomic layer deposition, the generation of square and hexagonal arrays of holes using focused ion beam milling, and the subsequent thermal reduction of the antidot arrays. Magnetic characterizations were carried out by magneto-optic Kerr effect measurements, showing the enhancement of the coercivity for the antidot arrays. AFIR opens a new route to manufacture ordered antidot arrays of magnetic oxides with variable lattice parameters.

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Field-controlled ultrafast magnetization dynamics in two-dimensional nanoscale ferromagnetic antidot arrays

Cited by 11 publications

References 41 publications

Magnetization dynamics of nanoscale magnetic materials: A perspective

Magnetization dynamics of nanoscale magnetic materials: A perspective

Tunability of Domain Structure and Magnonic Spectra in Antidot Arrays of Heusler Alloy

Magnetic properties of Fe₃O₄ antidot arrays synthesized by AFIR: atomic layer deposition, focused ion beam and thermal reduction

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Field-controlled ultrafast magnetization dynamics in two-dimensional nanoscale ferromagnetic antidot arrays

Cited by 11 publications

References 41 publications

Magnetization dynamics of nanoscale magnetic materials: A perspective

Magnetization dynamics of nanoscale magnetic materials: A perspective

Tunability of Domain Structure and Magnonic Spectra in Antidot Arrays of Heusler Alloy

Magnetic properties of Fe3O4 antidot arrays synthesized by AFIR: atomic layer deposition, focused ion beam and thermal reduction

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Magnetic properties of Fe₃O₄ antidot arrays synthesized by AFIR: atomic layer deposition, focused ion beam and thermal reduction