Chemical Control for the Morphogenesis of Conducting Polymer Dendrites in Water

TL;DR

This study explores how the chemical composition of water influences the growth and electrical properties of conducting polymer dendrites, offering guidelines to control their morphogenesis for potential use in adaptive electronic systems.

Contribution

It reveals the dependency of CPD morphogenesis on electrolyte and solvent chemistry, providing new insights into tuning their growth in aqueous environments.

Findings

CPDs' morphology varies with electrolyte type and concentration.

Chemical resources influence the growth dynamics and electrical properties.

Guidelines for tuning CPD evolution in water environments are proposed.

Abstract

Conducting polymer dendrite (CPD) morphogenesis is an electrochemical process that unlocks the potential to implement in materio evolving intelligence in electrical systems: As an electronic device experiences transient voltages in an open-space wet environment, electrically conductive structures physically change over time, programming the filtering properties of an interconnect as a non-linear analog device. Mimicking the self-preservation strategies of some sessile organisms, CPDs adapt their morphology to the environment they grow in. Either studied as an electrochemical experiment or as neuromorphic devices, the dependence of CPDs' electrical properties on the chemical nature of their environment is still unreported, despite the inter-dependence between the electrical properties of the electrogenerated material and the chemical composition of their growth medium. In this study, we report on the existing intrication between the nature and concentration of the electrolytes, electroactive compounds and co-solvents and the electrical and the electrochemical properties of CPDs in water. CPDs exhibit various chemical sensitivities in water: their morphology is highly dependent on the nature of the chemical resources available in their environment. The selection of these resources therefore critically influence morphogenesis. Also, concentrations have different impacts on growth dynamics, conditioning the balance between thermodynamic and kinetic control on polymer electrosynthesis. By correlating the dependencies of these evolving objects with the availability of the chemical resources in an aqueous environment, this study proposes guidelines to tune the degree of evolution of electronic materials in water. Such hardware is envisioned to exploit the chemical complexity of real world environments as part of information processing technologies.