Emergence of winner-takes-all connectivity paths in random nanowire networks

Manning, Hugh G.; Niosi, Fabio; Rocha, C. G.; Bellew, Allen T.; O’Callaghan, Colin; Biswas, Subhajit; Flowers, Patrick F.; Wiley, Ben J.; Holmes, Justin D.; Ferreira, M. S.; Boland, John J.

doi:10.1038/s41467-018-05517-6

Cited by 95 publications

(110 citation statements)

References 49 publications

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“…[275][276][277][278][279][280][281][282][283] In the following, resistive switching in stacked and planar devices based on NW networks is described. Resistive switching networks based on random ordered nanowires, dendritic, and fractal structures have attracted great attention because of the peculiar conduction properties that make these structures promising for resistive switching and neuromorphic applications.…”

Section: Resistive Switching In Nanowire Random Networkmentioning

confidence: 99%

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Recent Developments and Perspectives for Memristive Devices Based on Metal Oxide Nanowires

Milano

Porro

Valov

et al. 2019

Adv Elect Materials

101

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Memristive devices are considered one of the most promising candidates to overcome technological limitations for realizing next‐generation memories, logic applications, and neuromorphic systems in the modern nanoelectronics and information technology. Despite the continuous efforts, understanding the resistive switching mechanism underlying memristive/neuromorphic behavior still represents a challenge. Metal oxide nanowire‐based memristors appear suitable model systems for a deeper understanding of the involved physical/chemical phenomena due the possibility for localizing and investigating the switching mechanism. In practical aspects, nanowire‐based devices can be grown using a bottom‐up approach, thus being considered reliable candidates for going beyond the current scaling limitations of the top‐down approach by the standard lithography. In addition, taking into advantage of the high surface‐to‐volume ratio of these nanostructures, new device functionalities can be achieved by exploiting surface effects. In the literature, a variety of nanowire‐based devices such as single nanowires, nanowire arrays, and networks are reported to exhibit memristive behavior, explained by different switching mechanisms. This work provides a comparative review and a comprehensive analysis of device performances and physical phenomena responsible for memristive and neuromorphic behavior in such nanostructures. The analysis of the state‐of‐art of memristor devices based on nanowires and nanorods represent a milestone toward the development of nanowire‐based artificial neural networks.

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Section: Resistive Switching In Nanowire Random Networkmentioning

confidence: 99%

“…[275,277,[280][281][282][283] Thus, the global resistive switching behavior of the network arises from resistive switching events located at the numerous wire interconnections. Indeed, the NW network global properties arise from junctions between individual wires that determine the network connectivity.…”

Section: Planar Devicesmentioning

confidence: 99%

Recent Developments and Perspectives for Memristive Devices Based on Metal Oxide Nanowires

Milano

Porro

Valov

et al. 2019

Adv Elect Materials

101

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“…6,7 For instance, random networks of nanowires, nanoparticles, and clusters, embedded in a polymeric matrix or passivated by shell of ligands or oxide layers (insulator-conductor nanocomposites), show RS phenomena resulting in features typical of neuromorphic systems. 6,8 This has been attributed to either polymer breakdown between junctions or conducting lament formation between individual metallic nanoobjects. [9][10][11] The evolution of the electrical properties of such nanocomposites, upon the application of an electric eld, strongly depends on the volume fraction of the conductive phase and it can be described by the percolation theory.…”

Section: Introductionmentioning

confidence: 99%

Non-ohmic behavior and resistive switching of Au cluster-assembled films beyond the percolation threshold

et al. 2019

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“…Despite a bright future prospective for the development of next‐generation artificial intelligence (AI) systems, it is hard for such rigid top‐down architectures to emulate most typical features of biological neural networks such as high connectivity, adaptability through reconnection and rewiring, and long‐range spatio‐temporal correlation. Alternative ways using unconventional systems consisting of many interacting nano‐parts have been proposed for the realization of biologically plausible architectures where the emergent behavior arises from a complexity similar to that of biological neural circuits . However, these systems were unable to demonstrate bio‐realistic implementation of structural plasticity including reweighting and rewiring and spatio‐temporal processing of input signals similarly to our brain.…”

mentioning

confidence: 99%

“…By applying an over‐threshold constant voltage bias, the network conductance (synaptic weight) between two pads (neuron terminals) can be gradually increased (facilitation), as shown in Figure b (details in S7, Supporting Information). The gradual enhancement of network connectivity is related to cascade switching events of memristive elements constituting the network that self‐selects the lowest‐energy path for electronic conduction . After facilitation, the synaptic weight gradually relaxes back toward the initial state, exhibiting a volatile behavior due to the spontaneous dissolution of Ag conductive filaments previously formed in memristive elements of the network .…”

mentioning

confidence: 99%

Brain‐Inspired Structural Plasticity through Reweighting and Rewiring in Multi‐Terminal Self‐Organizing Memristive Nanowire Networks

Milano

Pedretti

Fretto

et al. 2020

Advanced Intelligent Systems

114

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Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building blocks for the realization of artificial neural networks. Current memristive crossbar architectures demonstrate the implementation of neuromorphic computing paradigms, although they are unable to emulate typical features of biological neural networks such as high connectivity, adaptability through reconnection and rewiring, and long‐range spatio‐temporal correlation. Herein, self‐organizing memristive random nanowire (NW) networks with functional connectivity able to display homo‐ and heterosynaptic plasticity is reported thanks to the mutual electrochemical interaction among memristive NWs and NW junctions. In particular, it is shown that rewiring and reweighting effects observed in single NWs and single NW junctions, respectively, are responsible for structural plasticity of the network under electrical stimulation. Such biologically inspired systems allow a low‐cost realization of neural networks that can learn and adapt when subjected to multiple external stimuli, emulating the experience‐dependent synaptic plasticity that shape the connectivity and functionalities of the nervous system that can be exploited for hardware implementation of unconventional computing paradigms.

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Emergence of winner-takes-all connectivity paths in random nanowire networks

Cited by 95 publications

References 49 publications

Recent Developments and Perspectives for Memristive Devices Based on Metal Oxide Nanowires

Recent Developments and Perspectives for Memristive Devices Based on Metal Oxide Nanowires

Non-ohmic behavior and resistive switching of Au cluster-assembled films beyond the percolation threshold

Brain‐Inspired Structural Plasticity through Reweighting and Rewiring in Multi‐Terminal Self‐Organizing Memristive Nanowire Networks

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