A compact skyrmionic leaky-integrate-fire spiking neuron device.

Neuromorphic computing, which relies on a combination of a large number of neurons massively interconnected by an even larger number of synapses, has been actively studied for its characteristics such as energy efficiency, intelligence, and adaptability. To date, while the development of artificial synapses has shown great progress with the introduction of emerging nanoelectronic devices, e.g., memristive devices, the implementation of artificial neurons, however, depends mostly on semiconductor-based circuits via integrating many transistors, sacrificing energy efficiency and integration density. Here, we present a novel compact neuron device that exploits the current-driven magnetic skyrmion dynamics in a wedge-shaped nanotrack. Under the coaction of the exciting current pulse and the repulsive force exerted by the nanotrack edges, the dynamic behavior of the proposed skyrmionic artificial neuron device is in analogy to the leaky-integrate-fire (LIF) spiking function of a biological neuron. The tunable temporary location of the skyrmion in our artificial neuron behaves like the analog membrane potential of a biological neuron. The neuronal dynamics and the related physical interpretations of the proposed skyrmionic neuron device are carefully investigated via micromagnetic and theoretical methods. Such a compact artificial neuron enables energy-efficient and high-density implementation of neuromorphic computing hardware.

[1]  Damien Querlioz,et al.  Spintronic Nanodevices for Bioinspired Computing , 2016, Proceedings of the IEEE.

[2]  A. Fert,et al.  Skyrmions on the track. , 2013, Nature nanotechnology.

[3]  Yu-heng Zhang,et al.  Edge-mediated skyrmion chain and its collective dynamics in a confined geometry , 2015, Nature Communications.

[4]  Yan Zhou,et al.  Magnetic skyrmion-based synaptic devices , 2016, Nanotechnology.

[5]  A. Fert,et al.  Magnetic skyrmions: advances in physics and potential applications , 2017 .

[6]  S. Heinze,et al.  Electrical detection of magnetic skyrmions by tunnelling non-collinear magnetoresistance. , 2015, Nature nanotechnology.

[7]  J. Zang,et al.  Dynamics of an insulating Skyrmion under a temperature gradient. , 2013, Physical review letters.

[8]  R M Borisyuk,et al.  Information coding on the basis of synchronization of neuronal activity. , 1997, Bio Systems.

[9]  S. Blügel,et al.  Perpendicular reading of single confined magnetic skyrmions , 2015, Nature Communications.

[10]  Kaushik Roy,et al.  Spin-Orbit Torque Induced Spike-Timing Dependent Plasticity , 2014, ArXiv.

[11]  L. You,et al.  Magnetic skyrmions without the skyrmion Hall effect in a magnetic nanotrack with perpendicular anisotropy. , 2017, Nanoscale.

[12]  Roland Wiesendanger,et al.  Skyrmions at the Edge: Confinement Effects in Fe/Ir(111). , 2016, Physical review letters.

[13]  A. Stashkevich,et al.  Current-induced skyrmion generation and dynamics in symmetric bilayers , 2016, Nature Communications.

[14]  Yan Zhou,et al.  Skyrmion-Electronics: An Overview and Outlook , 2016, Proceedings of the IEEE.

[15]  G. Finocchio,et al.  A strategy for the design of skyrmion racetrack memories , 2014, Scientific Reports.

[16]  Vishal Saxena,et al.  A CMOS Spiking Neuron for Brain-Inspired Neural Networks With Resistive Synapses and In Situ Learning , 2015, IEEE Transactions on Circuits and Systems II: Express Briefs.

[17]  Shimeng Yu,et al.  Synaptic electronics: materials, devices and applications , 2013, Nanotechnology.

[18]  M. Rozenberg,et al.  A Leaky‐Integrate‐and‐Fire Neuron Analog Realized with a Mott Insulator , 2017 .

[19]  R. Wiesendanger,et al.  Spin-polarized scanning tunneling microscopy study of 360° walls in an external magnetic field , 2003 .

[20]  D. Pierce,et al.  Realization of ground-state artificial skyrmion lattices at room temperature , 2015, Nature Communications.

[21]  C. Wright,et al.  Beyond von‐Neumann Computing with Nanoscale Phase‐Change Memory Devices , 2013 .

[22]  Byoungil Lee,et al.  Nanoelectronic programmable synapses based on phase change materials for brain-inspired computing. , 2012, Nano letters.

[23]  R. Wiesendanger,et al.  Field-dependent size and shape of single magnetic Skyrmions. , 2015, Physical review letters.

[24]  Kang L. Wang,et al.  Direct observation of the skyrmion Hall effect , 2016, Nature Physics.

[25]  Yan Zhou,et al.  Magnetic skyrmion-based artificial neuron device , 2017, Nanotechnology.

[26]  Keisuke Yamada,et al.  Electrical detection of magnetic states in crossed nanowires using the topological Hall effect , 2017, 1703.06051.

[27]  W. Lew,et al.  Efficient skyrmion transport mediated by a voltage controlled magnetic anisotropy gradient. , 2018, Nanoscale.

[28]  J. Zang,et al.  Skyrmions in magnetic multilayers , 2017, 1706.08295.

[29]  Avadh Saxena,et al.  ac current generation in chiral magnetic insulators and Skyrmion motion induced by the spin Seebeck effect. , 2013, Physical review letters.

[30]  Farnood Merrikh-Bayat,et al.  Training and operation of an integrated neuromorphic network based on metal-oxide memristors , 2014, Nature.

[31]  Wei Yang Lu,et al.  Nanoscale memristor device as synapse in neuromorphic systems. , 2010, Nano letters.

[32]  Manuel Le Gallo,et al.  Stochastic phase-change neurons. , 2016, Nature nanotechnology.

[33]  Yan Zhou,et al.  Magnetic skyrmion transistor: skyrmion motion in a voltage-gated nanotrack , 2015, Scientific Reports.

[34]  Lars Heinke,et al.  The surface barrier phenomenon at the loading of metal-organic frameworks , 2014, Nature Communications.

[35]  Fei Zhou,et al.  Demonstration of Synaptic Behaviors and Resistive Switching Characterizations by Proton Exchange Reactions in Silicon Oxide , 2016, Scientific Reports.

[36]  Hans Fangohr,et al.  Hysteresis of nanocylinders with Dzyaloshinskii-Moriya interaction , 2016, 1606.05181.

[37]  Davood Shahrjerdi,et al.  A sub-1-volt analog metal oxide memristive-based synaptic device with large conductance change for energy-efficient spike-based computing systems , 2016, 1603.03979.

[38]  Yan Zhou,et al.  Skyrmion dynamics in width-varying nanotracks and implications for skyrmionic applications , 2017 .

[39]  Yan Zhou,et al.  Magnetic skyrmion logic gates: conversion, duplication and merging of skyrmions , 2014, Scientific Reports.

[40]  Yan Zhou,et al.  Magnetic bilayer-skyrmions without skyrmion Hall effect , 2015, Nature Communications.