(259f) Electrochemical Synthesis of Bulk Copper-Carbon Nanotube Composites

In this work, we introduce a new method to create a uniform Cu-CNT composite from an isotropic CNT mat in single step electrodeposition using an electrolyte solution modified to have a marginally wetting contact angle. We first describe the requirements to transition from nonwetting to wetting systems using chemical additives to our electrolyte solution, and how these additives influence the Faradaic efficiency of electrodeposition, appearance of copper nucleation, percolation, and final composite conductivity. We describe the limits of Cu penetration into dense initial CNT networks using electron dispersion spectrographs of cross-sections of experimental specimens.

We conclude by introducing a processing diagram mapping of the copper deposition mass and composite conductivity as a function of the input current density and time of application of current. We achieve control of the final conductivity over several orders of magnitude up to 2 MS/m for a lightweight composite with density up to 0.8 g/cm3. We finally discuss the limits to homogeneous Cu concentration and process speed, and reflect on requirements to turn this into a scalable process, e.g., for scalable Cu-CNT wire manufacturing.