Nanowire networks are promising memristive architectures for neuromorphic applications due to their connectivity and neurosynaptic-like behaviours. Here, we demonstrate a self-similar scaling of the conductance of networks and the junctions that comprise them. We show this behavior is an emergent property of any junction-dominated network. A particular class of junctions naturally leads to the emergence of conductance plateaus and a “winner-takes-all” conducting path that spans the entire network, and which we show corresponds to the lowest-energy connectivity path. The memory stored in the conductance state is distributed across the network but encoded in specific connectivity pathways, similar to that found in biological systems. These re...
Electrical transport in networked materials occurs through percolative clusters composed of a random...
Networks of nanowires are currently being explored for a range of applications in brain-like (or neu...
Over the past few decades, machine learning has become integral to our daily lives. Deep learning h...
Nanowire networks are promising memristive architectures for neuromorphic computing applications due...
Nanowire networks have had much attention from the scientific community in the past two decades due ...
Random nanowire networks (NWNs) are promising synthetic architectures for non-volatile memory device...
The brain’s unique information processing efficiency has inspired the development of neuromorphic, o...
Biological neuronal networks are characterized by nonlinear interactions and complex connectivity. G...
We present simulation results based on a model of self–assembled nanowire networks with memristive j...
The brain's efficient information processing is enabled by the interplay between its neuro-synaptic ...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
Engineering smart-materials with emergent properties requires designing and characterizing systems w...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Neuromorphic computing aims at the realization of intelligent systems able to process information si...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Electrical transport in networked materials occurs through percolative clusters composed of a random...
Networks of nanowires are currently being explored for a range of applications in brain-like (or neu...
Over the past few decades, machine learning has become integral to our daily lives. Deep learning h...
Nanowire networks are promising memristive architectures for neuromorphic computing applications due...
Nanowire networks have had much attention from the scientific community in the past two decades due ...
Random nanowire networks (NWNs) are promising synthetic architectures for non-volatile memory device...
The brain’s unique information processing efficiency has inspired the development of neuromorphic, o...
Biological neuronal networks are characterized by nonlinear interactions and complex connectivity. G...
We present simulation results based on a model of self–assembled nanowire networks with memristive j...
The brain's efficient information processing is enabled by the interplay between its neuro-synaptic ...
Neuromorphic networks are formed by random self-assembly of silver nanowires. Silver nanowires are c...
Engineering smart-materials with emergent properties requires designing and characterizing systems w...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Neuromorphic computing aims at the realization of intelligent systems able to process information si...
Acting as artificial synapses, two‐terminal memristive devices are considered fundamental building b...
Electrical transport in networked materials occurs through percolative clusters composed of a random...
Networks of nanowires are currently being explored for a range of applications in brain-like (or neu...
Over the past few decades, machine learning has become integral to our daily lives. Deep learning h...