Chemically regulated conical channel synapse for neuromorphic and sensing applications

Publication date

2025-03-31

Authors

Kamsma, TimORCID 0000-0002-8898-8337ISNI 0000000523924190
Klop, M. S.
Boon, Willem QuirinISNI 000000050633771X
Spitoni, CristianORCID 0000-0003-0192-606XISNI 0000000398006090
Rueckauer, B.
Roij, René vanISNI 0000000392993654

Editors

Advisors

Supervisors

Document Type

Article
Open Access logo

License

cc_by

Abstract

Fluidic iontronics offer a unique capability for emulating the chemical processes found in neurons. We extract multiple distinct chemically regulated synaptic features from an experimentally accessible conical microfluidic channel carrying functionalized surface groups, using finite-element calculations of continuum transport equations. By modeling a Langmuir-type surface reaction on the channel wall, we couple fast voltage-induced volumetric salt accumulation with a long-term channel surface charge modulation by means of fast charging and slow discharging. These nonlinear charging dynamics emerge across several orders of magnitude of reaction rates and equilibria, and are understood through an analytic approximation rooted in first principles. We show how short- and long-term potentiation and depression, frequency-dependent plasticity, and chemical-electrical signal spike-timing dependence and coincidence detection (acting like a chemical-electrical AND logic gate), akin to the NMDA mechanism for Hebbian learning in biological synapses, can all be emulated.

Keywords

General Physics and Astronomy

Citation

Kamsma, T M, Klop, M S, Boon, W Q, Spitoni, C, Rueckauer, B & van Roij, R 2025, 'Chemically regulated conical channel synapse for neuromorphic and sensing applications', Physical Review Research, vol. 7, no. 1, 013328 , pp. 1-8. https://doi.org/10.1103/PhysRevResearch.7.013328