Dendritic organic electrochemical transistors grown by electropolymerization for 3D neuromorphic engineering

Abstract: One of the major limitation of standard top-down technologies used in today's neuromorphic engineering is their inability to map the 3D nature of biological brains. Here, we show how bipolar electropolymerization can be used to engineer 3D networks of PEDOT:PSS dendritic fibers. By controlling the growth conditions of the electropolymerized material, we investigate how dendritic fibers can reproduce structural plasticity by creating structures of controllable shape. We demonstrate gradual topologies evolution in a multi-electrode configuration. We conduct a detail electrical characterization of the PEDOT:PSS dendrites through DC and impedance spectroscopy measurements and we show how organic electrochemical transistors (OECT) can be realized with these structures. These measurements reveal that quasi-static and transient response of OECTs can be adjust by controlling dendrites' morphologies. The unique properties of organic dendrites are used to demonstrate short-term, long-term and structural plasticity, which are essential features required for future neuromorphic hardware development.