Toward Efficient Electrokinetic Energy Conversion with Topographic Modulation of Electrical Conduction

This work presents experimental and theoretical analyses of electrokinetic flow in microchannels with glass and silica surfaces across a broad range of electrolyte concentrations (0.01 to 100 mM). We demonstrate simple but effective strategies for controlling electrical conduction by engineering nanoscale and microscale topographic features that directly modify the structure and extent of the electric double layer (EDL) and the interfacial ion conduction pathway. These tailored surface topographies modulate the overall electrical conductivity in slit microchannels through similar phenomena documented for nanochannels and nanopores due to the presence of liquid-filled nanoscale topographic features with high concentration of highly mobile protons. The findings of this work reveal that the interaction between tailored surface features and the EDL can substantially enhance energy conversion efficiency in microscale systems. These insights along with simple analytical models provide guidance for the rational design and optimization of scalable electrokinetic devices and are broadly relevant to numerous energy harvesting and charge-separation technologies.