Self-assembled networks of nanoparticles and nanowires have recently emerged as promising systems for brain-like computation. Here we focus on percolating networks of nanoparticles which exhibit brain-like dynamics. We use a combination of experiments and simulations to show that the brain-like network dynamics emerge from atomic-scale switching dynamics inside tunnel gaps that are distributed throughout the network. The atomic-scale dynamics emulate leaky integrate and fire (LIF) mechanisms in biological neurons leading to the generation of critical avalanches of signals. These avalanches are quantitatively the same as those observed in cortical tissue and are signatures of the correlations that are required for computation. We show ...
Networks of living neurons exhibit diverse patterns of activity, including oscillations, synchrony, ...
Neuromorphic computing systems may be the future of computing and cluster-based networks are a promi...
Neuronal avalanches measured in vitro and in vivo in different cortical networks consistently exhibi...
The brain's efficient information processing is enabled by the interplay between its neuro-synaptic ...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
Abstract We show that the complex connectivity of percolating networks of nanoparticles pr...
© 2020 Massachusetts Institute of Technology. Biological neuronal networks are the computing engines...
IEEE Nature-inspired neuromorphic architectures are being explored as an alternative to imminent lim...
Neuromorphic nanowire networks are found to exhibit neural-like dynamics, including phase transition...
Computers have grown exponentially more powerful for decades, and so too has their ubiquity in human...
Conventional computer power has increased dramatically over the last 50 years due to reduction in th...
Experimental evidence shows that resting neuronal activity consists of power-law distributed outburs...
A self-organising model is proposed to explain the criticality in cortical networks deduced from rec...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
Networks of living neurons exhibit an avalanche mode of activity, experimentally found in organotypi...
Networks of living neurons exhibit diverse patterns of activity, including oscillations, synchrony, ...
Neuromorphic computing systems may be the future of computing and cluster-based networks are a promi...
Neuronal avalanches measured in vitro and in vivo in different cortical networks consistently exhibi...
The brain's efficient information processing is enabled by the interplay between its neuro-synaptic ...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
Abstract We show that the complex connectivity of percolating networks of nanoparticles pr...
© 2020 Massachusetts Institute of Technology. Biological neuronal networks are the computing engines...
IEEE Nature-inspired neuromorphic architectures are being explored as an alternative to imminent lim...
Neuromorphic nanowire networks are found to exhibit neural-like dynamics, including phase transition...
Computers have grown exponentially more powerful for decades, and so too has their ubiquity in human...
Conventional computer power has increased dramatically over the last 50 years due to reduction in th...
Experimental evidence shows that resting neuronal activity consists of power-law distributed outburs...
A self-organising model is proposed to explain the criticality in cortical networks deduced from rec...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
Networks of living neurons exhibit an avalanche mode of activity, experimentally found in organotypi...
Networks of living neurons exhibit diverse patterns of activity, including oscillations, synchrony, ...
Neuromorphic computing systems may be the future of computing and cluster-based networks are a promi...
Neuronal avalanches measured in vitro and in vivo in different cortical networks consistently exhibi...