IEEE Nature-inspired neuromorphic architectures are being explored as an alternative to imminent limitations of conventional complementary metal-oxide semiconductor architectures. Utilization of such architectures for practical applications like advanced pattern recognition tasks will require synaptic connections that are both reconfigurable and stable. Here, we report realization of stable atomic-switch networks (ASNs), with inherent complex connectivity, self-assembled from percolating metal nanoparticles (NPs). The device conductance reflects the configuration of synapses, which can be modulated via voltage stimulus. By controlling Relative Humidity and oxygen partial-pressure during NP deposition, we obtain stochastic conductance switch...
Molecule-based devices are envisioned to complement silicon devices by providing new functions or al...
The race towards smarter and more efficient computers is at the core of our technology industry and ...
Memristive devices are attracting a great attention for memory, logic, neural networks, and sensing ...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
The emergent dynamical behaviors of biological neuronal networks and other natural, complex systems ...
Efforts to emulate the formidable information processing capabilities of the brain through neuromorp...
Efforts to emulate the formidable information processing capabilities of the brain through neuromorp...
Conventional computer power has increased dramatically over the last 50 years due to reduction in th...
The past decade has seen a sharp rise in the development and manufacture of different hardware frame...
Computers have grown exponentially more powerful for decades, and so too has their ubiquity in human...
Self-assembled networks of nanoparticles and nanowires have recently emerged as promising systems f...
Abstract We show that the complex connectivity of percolating networks of nanoparticles pr...
Nanoionic device-based artificial neural networks that consume little power and hold a potential for...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
We describe the memristive properties of cluster-assembled gold films. We show that resistive switch...
Molecule-based devices are envisioned to complement silicon devices by providing new functions or al...
The race towards smarter and more efficient computers is at the core of our technology industry and ...
Memristive devices are attracting a great attention for memory, logic, neural networks, and sensing ...
We report a detailed study of neuromorphic switching behaviour in inherently complex percolating net...
The emergent dynamical behaviors of biological neuronal networks and other natural, complex systems ...
Efforts to emulate the formidable information processing capabilities of the brain through neuromorp...
Efforts to emulate the formidable information processing capabilities of the brain through neuromorp...
Conventional computer power has increased dramatically over the last 50 years due to reduction in th...
The past decade has seen a sharp rise in the development and manufacture of different hardware frame...
Computers have grown exponentially more powerful for decades, and so too has their ubiquity in human...
Self-assembled networks of nanoparticles and nanowires have recently emerged as promising systems f...
Abstract We show that the complex connectivity of percolating networks of nanoparticles pr...
Nanoionic device-based artificial neural networks that consume little power and hold a potential for...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
We describe the memristive properties of cluster-assembled gold films. We show that resistive switch...
Molecule-based devices are envisioned to complement silicon devices by providing new functions or al...
The race towards smarter and more efficient computers is at the core of our technology industry and ...
Memristive devices are attracting a great attention for memory, logic, neural networks, and sensing ...