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Iontronic Nanopore Model for Artificial Neurons: The Requisites of Spiking

Juan Bisquert

2023The Journal of Physical Chemistry Letters23 citationsDOI

Abstract

Brain-inspired neuromorphic computing is currently being investigated for effective artificial intelligence (AI) systems. The development of artificial neurons and synapses is imperative to creating efficient computational biomimetic networks. Here we propose the minimal configuration of an effective iontronic spiking neuron based on a conical nanofluidic pore ionic diode. The conductance is composed of a Boltzmann open channel probability and a blocking inactivation function, forming the structure of a memristor. The presence of a negative resistance and the combination of activation-deactivation dynamics cause a Hopf bifurcation. Using the characteristic frequencies of small perturbation impedance spectroscopy, we discuss the conditions of spiking, in which the system enters a limit cycle oscillation. We arrive at the conclusion that an excitable neuron-like system can be made with a single active channel instead of the more complex combination of multiple channels that occurs in the Hodgkin-Huxley neuron model.

Topics & Concepts

Neuromorphic engineeringMemristorHodgkin–Huxley modelComputer scienceSpiking neural networkBiological systemBifurcationArtificial neuronNeuronBiological neuron modelOscillation (cell signaling)Artificial neural networkArtificial intelligenceTopology (electrical circuits)PhysicsChemistryNeuroscienceElectronic engineeringEngineeringBiologyNonlinear systemElectrical engineeringBiochemistryQuantum mechanicsAdvanced Memory and Neural ComputingNeural dynamics and brain functionNeuroscience and Neural Engineering
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