Numerical Model for 32-Bit Magnonic Ripple Carry Adder

Garlando, Umberto; Wang, Q.; Dobrovolskiy, Oleksandr V.; Chumak, A. V.; Riente, Fabrizio

doi:10.1109/tetc.2023.3238581

Cited by 11 publications

(2 citation statements)

References 47 publications

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“…1 and is proposed to be installed at the input of each magnonic logic gate to receive damped and distorted spin-wave signals from the upper-level logic gate, clean them up, and then regenerate new spin waves with amplified amplitude (with the gain up to 6 times) and normalized phase to connect the next level logic gate. This opens the door to cascading magnonic logic elements with amplitude information encoding, allowing the practical realization of complex Boolean circuits predicted in theory [27] as well as the realization of magnonic synapses in neuromorphic networks.…”

Section: Introductionmentioning

confidence: 99%

All-magnonic repeater based on bistability

Wang,

Verba,

Davídková

et al. 2024

Preprint

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Bistability, a universal phenomenon found in diverse fields such as biology, chemistry, and physics, describes a scenario in which a system has two stable equilibrium states and resets to one of the two states. The ability to switch between these two states is the basis for a wide range of applications, particularly in memory and logic operations. Here, we present a universal approach to achieve bistable switching in magnonics, the field processing data using spin waves. As an exemplary application, we use magnonic bistability to experimentally demonstrate the still missing magnonic repeater. A pronounced bistable window is observed in a 1 μm wide magnonic conduit under an external rf drive characterized by two magnonic stable states defined as low and high spin-wave amplitudes. The switching between these two states is realized by another propagating spin wave sent into the rf driven region. This magnonic bistable switching is used to design the magnonic repeater, which receives the original decayed and distorted spin wave and regenerates a new spin wave with amplified amplitude and normalized phase. Our magnonic repeater is proposed to be installed at the inputs of each magnonic logic gate to overcome the spin-wave amplitude degradation and phase distortion during previous propagation and achieve integrated magnonic circuits or magnonic neuromorphic networks.

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Section: Introductionmentioning

confidence: 99%

All-magnonic repeater based on bistability

Wang,

Verba,

Davídková

et al. 2024

Preprint

Self Cite

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show abstract

“…Three-dimensional magnonics is now attracting increasing attention [ 26 ]. This interest is further motivated by the fundamental physical phenomena associated with hierarchical systems [ 27 ], systems with magnetic frustration [ 28 ], and geometrically induced non-trivial spin textures [ 29 ]. In this regard, of particular interest are 3D curvilinear systems, which have already demonstrated applications-relevant behaviour, such as non-reciprocity and stabilisation of topological spin textures [ 22 , 30 ].…”

Section: Introductionmentioning

confidence: 99%

3D Magnonic Conduits by Direct Write Nanofabrication

et al. 2023

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Magnonics is a rapidly developing domain of nanomagnetism, with application potential in information processing systems. Realisation of this potential and miniaturisation of magnonic circuits requires their extension into the third dimension. However, so far, magnonic conduits are largely limited to thin films and 2D structures. Here, we introduce 3D magnonic nanoconduits fabricated by the direct write technique of focused-electron-beam induced deposition (FEBID). We use Brillouin light scattering (BLS) spectroscopy to demonstrate significant qualitative differences in spatially resolved spin-wave resonances of 2D and 3D nanostructures, which originates from the geometrically induced non-uniformity of the internal magnetic field. This work demonstrates the capability of FEBID as an additive manufacturing technique to produce magnetic 3D nanoarchitectures and presents the first report of BLS spectroscopy characterisation of FEBID conduits.

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All-magnonic repeater based on bistability

Wang,

Verba,

Davídková

et al. 2024

Nat Commun

View full text Add to dashboard Cite

Bistability, a universal phenomenon found in diverse fields such as biology, chemistry, and physics, describes a scenario in which a system has two stable equilibrium states and resets to one of the two states. The ability to switch between these two states is the basis for a wide range of applications, particularly in memory and logic operations. Here, we present a universal approach to achieve bistable switching in magnonics, the field processing data using spin waves. A pronounced bistable window is observed in a 1 μm wide magnonic conduit under an external rf drive. The system is characterized by two magnonic stable states defined as low and high spin-wave amplitude states. The switching between these two states is realized by another propagating spin wave sent into the rf driven region. This magnonic bistable switching is used to design a magnonic repeater, which receives the original decayed and distorted spin wave and regenerates a new spin wave with amplified amplitude and normalized phase. Our magnonic repeater can be installed at the inputs of each magnonic logic gate to overcome the spin-wave amplitude degradation and phase distortion during previous propagation and achieve integrated magnonic circuits or magnonic neuromorphic networks.

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Numerical Model for 32-Bit Magnonic Ripple Carry Adder

Cited by 11 publications

References 47 publications

All-magnonic repeater based on bistability

All-magnonic repeater based on bistability

3D Magnonic Conduits by Direct Write Nanofabrication

All-magnonic repeater based on bistability

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