Litcius/Paper detail

Hybrid microfabrication of 3D pyrolytic carbon electrodes by photolithography and additive manufacturing

Jesper Yue Pan, Babak Rezaei, Thomas Aarøe Anhøj, Niels B. Larsen, Stephan Sylvest Keller

2022Micro and Nano Engineering14 citationsDOIOpen Access PDF

Abstract

We report a novel hybrid method for fabricating high aspect ratio 3D pyrolytic carbon electrodes combining UV photolithography and additive manufacturing with commercially available SLA 3D printers and materials. By using a 3D printed chip holder, aligned 3D printing on a patterned silicon chip was possible. This allowed for the fabrication of cylindrical polymer micropillars with a height of 2173 ± 26 μm and a width of 316 ± 11 μm on SU-8 precursor structures defining the leads, contact pads and underlying 2D electrode prepared using UV lithography. Microfabrication of 3D structures with these dimensions is impossible to achieve with SU-8 photolithography alone. The hybrid polymer structures were converted into 3D carbon electrodes with high structural integrity using a 3-step pyrolysis process optimized for the specific 3D print resin. During this process, the micropillars shrunk to 30 ± 3% in height and 35 ± 1% in width of the polymer precursor structures, while maintaining the macroscopic shape and microscopic surface roughness. Electrochemical experiments confirmed that the pyrolytic carbon formed a monolithic conductive 3D electrode. The surface roughness contributed to a 17 ± 5% increase in electroactive surface area compared to the geometrical surface area of the micropillars.

Topics & Concepts

MicrofabricationPyrolytic carbonPhotolithographyMaterials scienceLithographyElectrodeSurface roughnessFabricationNanotechnologyPolymer3D printingOptoelectronicsComposite materialPyrolysisChemical engineeringMedicineEngineeringChemistryAlternative medicinePathologyPhysical chemistryConducting polymers and applicationsAdvanced Sensor and Energy Harvesting MaterialsElectrochemical sensors and biosensors