TY - JOUR
T1 - Neuromimetic circuits with synaptic devices based on strongly correlated electron systems
AU - Ha, Sieu D.
AU - Shi, Jian
AU - Meroz, Yasmine
AU - Mahadevan, L.
AU - Ramanathan, Shriram
N1 - Publisher Copyright:
© 2014 American Physical Society.
PY - 2014/12/4
Y1 - 2014/12/4
N2 - Strongly correlated electron systems such as the rare-earth nickelates (RNiO3, R denotes a rare-earth element) can exhibit synapselike continuous long-term potentiation and depression when gated with ionic liquids; exploiting the extreme sensitivity of coupled charge, spin, orbital, and lattice degrees of freedom to stoichiometry. We present experimental real-time, device-level classical conditioning and unlearning using nickelate-based synaptic devices in an electronic circuit compatible with both excitatory and inhibitory neurons. We establish a physical model for the device behavior based on electric-field-driven coupled ionic-electronic diffusion that can be utilized for design of more complex systems. We use the model to simulate a variety of associate and nonassociative learning mechanisms, as well as a feedforward recurrent network for storing memory. Our circuit intuitively parallels biological neural architectures, and it can be readily generalized to other forms of cellular learning and extinction. The simulation of neural function with electronic device analogs may provide insight into biological processes such as decision making, learning, and adaptation, while facilitating advanced parallel information processing in hardware.
AB - Strongly correlated electron systems such as the rare-earth nickelates (RNiO3, R denotes a rare-earth element) can exhibit synapselike continuous long-term potentiation and depression when gated with ionic liquids; exploiting the extreme sensitivity of coupled charge, spin, orbital, and lattice degrees of freedom to stoichiometry. We present experimental real-time, device-level classical conditioning and unlearning using nickelate-based synaptic devices in an electronic circuit compatible with both excitatory and inhibitory neurons. We establish a physical model for the device behavior based on electric-field-driven coupled ionic-electronic diffusion that can be utilized for design of more complex systems. We use the model to simulate a variety of associate and nonassociative learning mechanisms, as well as a feedforward recurrent network for storing memory. Our circuit intuitively parallels biological neural architectures, and it can be readily generalized to other forms of cellular learning and extinction. The simulation of neural function with electronic device analogs may provide insight into biological processes such as decision making, learning, and adaptation, while facilitating advanced parallel information processing in hardware.
UR - http://www.scopus.com/inward/record.url?scp=84937453832&partnerID=8YFLogxK
U2 - 10.1103/PhysRevApplied.2.064003
DO - 10.1103/PhysRevApplied.2.064003
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AN - SCOPUS:84937453832
SN - 2331-7019
VL - 2
JO - Physical Review Applied
JF - Physical Review Applied
IS - 6
M1 - 064003
ER -