Bias field orientation driven reconfigurable magnonics and magnon−magnon coupling in triangular shaped Ni<sub>80</sub>Fe<sub>20</sub> nanodot arrays

Mondal, Amrit Kumar; Majumder, Sudip; Mahato, Bipul Kumar; Barman, Saswati; Otani, Y.; Barman, Anjan

doi:10.1088/1361-6528/acae5e

Cited by 8 publications

(9 citation statements)

References 61 publications

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“…Recognizing these challenges, the field underwent a transition towards nanoscale magnonics, driven by the aspiration for enhanced miniaturization and compatibility with complementary metal-oxidesemiconductor technology. In response to the identified gaps in current research, recent literature has made substantial strides in unveiling the intricate phenomenon of magnon-magnon coupling within irregularly shaped hexagonal dots [50], triangular [61], diamond nanodots [62], cross-shaped nanomagnets [63][64][65], and nanoring arrays [66]. These investigations represent a pivotal advancement towards bridging the existing knowledge deficiencies in the field.…”

Section: Magnon-magnon Coupling In Magnetic Nanostructuresmentioning

confidence: 99%

Using magnons as a quantum technology platform: a perspective

Pal,

Mondal,

Barman

2024

J. Phys.: Condens. Matter

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Traditional electronics rely on charge currents for controlling and transmitting information, resulting in energy dissipation due to electron scattering. Over the last decade, magnons, quanta of spin waves, have emerged as a promising alternative. This perspective article provides a brief review of experimental and theoretical studies on quantum and hybrid magnonics resulting from the interaction of magnons with other quasiparticles in the GHz frequency range, offering insights into the development of functional magnonic devices. In this process, we discuss recent advancements in the quantum theory of magnons and their coupling with various types of qubits in nanoscale ferromagnets, antiferromagnets, synthetic antiferromagnets, and magnetic bulk systems. Additionally, we explore potential technological platforms that enable new functionalities in magnonics, concluding with future directions and emerging phenomena in this burgeoning field.

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Section: Magnon-magnon Coupling In Magnetic Nanostructuresmentioning

confidence: 99%

Using magnons as a quantum technology platform: a perspective

Pal,

Mondal,

Barman

2024

J. Phys.: Condens. Matter

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“…In the last decade, extensive studies have been done using both confined and propagating magnons in the field of magnonics, which emerged as an exciting field of research. To this end single nanomagnets have been studied extensively due to their geometrically confined rich volume and localized magnetic modes [25][26][27][28][29][30][31] in nanometer dimension and their tunability with different external parameters. Therefore, such systems possess great potential in quantum magnonics with the possibility of developing magnon-based on-chip quantum information processing systems in the GHz and THz frequency range with high energy efficiency.…”

Section: Introductionmentioning

confidence: 99%

Tunable strong magnon-magnon coupling in two-dimensional array of diamond shaped ferromagnetic nanodots

Majumder,

Choudhury,

Barman

et al. 2024

Phys. Scr.

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Hybrid magnonics involving coupling between magnons and different quantum particles have been extensively studied during past few years for varied interests including quantum electrodynamics. In such systems, magnons in magnetic materials with high spin density are utilized where the “coupling strength” is collectively enhanced by the square root of the number of spins to overcome the weaker coupling between individual spins and the microwave field. However, achievement of strong magnon-magnon coupling in a confined nanomagnets would be essential for on-chip integration of such hybrid systems. Here, through intensive study of interaction between different magnon modes in a Ni80Fe20 (Py) nanodot array, we demonstrate that the intermodal coupling can approach the strong coupling regime with coupling strength up to 0.82 GHz and cooperativity of 2.51. Micromagnetic simulations reveal that the intermodal coupling is mediated by the exchange field inside each nanodot. Micromagnetic Simulations reveal that anticrossing occurs due to change in exchange configuration (Symmetry breaking). The coupling strength could be continuously tuned by varying the bias field (Hext) strength and orientation (φ), opening routes for external control over hybrid magnonic systems. These findings could greatly enrich the rapidly evolving field of quantum magnonics.

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“…During the past two decades, fundamental research on nanoscale magnonics has demonstrated great promise in developing next-generation high-speed and energy-efficient technology. Novel nanopatterned magnetic structures have emerged as the elevators for upsurging this exciting research field. − Magnonics render several prime advantages, e.g., shorter wavelength of spin-wave (SW) or magnon, large scalability, nonreciprocity, waveguiding property, nonlinearity, anisotropic dispersion, reconfigurable band structure, and hybridization with other quasi-particles, leading to the possibility of its myriad applications. − These potential applications of magnonics are envisaged with low-loss sustainability, such as SW filter, − transistor, , phase shifter, multiplexer, logic gates, − directional couplers, memory, SW diodes, − and nonreciprocal devices in addition to wave-based computing, , signal processing, and more recently in neuromorphic computing. − Such rapid progress toward future technology demands the exploration of fundamental physics in a variety of systems including bi- and multicomponent magnonic crystals, which may provide perfect testbeds for tuning the dipole-exchange coupling of the nanomagnets.…”

Section: Introductionmentioning

confidence: 99%

Active Control of Dipole-Exchange Coupled Magnon Modes in Nanoscale Bicomponent Magnonic Crystals

Adhikari

Majumder

Otani

et al. 2023

ACS Appl. Nano Mater.

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Bicomponent magnonic crystals (BMCs) are metasurfaces formed using two dissimilar materials, which offer a richer manipulation of spin waves and promising spin-wavebased computation, communication, and signal processing. Here, the intricate interplay of spin dynamics between two different materials Co 50 Fe 50 and Ni 80 Fe 20 forming a BMC is exploited experimentally. Optimally engineered interface leads to interelement exchange coupling combined with the long-range dipolar coupling as confirmed by micromagnetic simulations. These couplings have been further tuned by systematic variation of the filling fraction of Co 50 Fe 50 and Ni 80 Fe 20 in the BMC. Moreover, the characteristic properties of spinwave spectra are found to be highly sensitive to the bias-field strength. Further numerical simulations based on experimentally determined parameters demonstrate long-distance and high-speed spin-wave propagation in such BMCs controlled by the filling fraction and offer a diode-like on/off mechanism determined by the applied magnetic field strength. These observations will lead to the development of high-speed reconfigurable magnonic devices controlled by external parameters.

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Bias field orientation driven reconfigurable magnonics and magnon−magnon coupling in triangular shaped Ni₈₀Fe₂₀ nanodot arrays

Cited by 8 publications

References 61 publications

Using magnons as a quantum technology platform: a perspective

Using magnons as a quantum technology platform: a perspective

Tunable strong magnon-magnon coupling in two-dimensional array of diamond shaped ferromagnetic nanodots

Active Control of Dipole-Exchange Coupled Magnon Modes in Nanoscale Bicomponent Magnonic Crystals

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Bias field orientation driven reconfigurable magnonics and magnon−magnon coupling in triangular shaped Ni80Fe20 nanodot arrays

Cited by 8 publications

References 61 publications

Using magnons as a quantum technology platform: a perspective

Using magnons as a quantum technology platform: a perspective

Tunable strong magnon-magnon coupling in two-dimensional array of diamond shaped ferromagnetic nanodots

Active Control of Dipole-Exchange Coupled Magnon Modes in Nanoscale Bicomponent Magnonic Crystals

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Bias field orientation driven reconfigurable magnonics and magnon−magnon coupling in triangular shaped Ni₈₀Fe₂₀ nanodot arrays