Laser Printing of Multilayered Alternately Conducting and Insulating Microstructures
Eitan Edri, Nina Armon, Ehud Greenberg, Shlomit Moshe-Tsurel, Danielle Lubotzky, Tommaso Salzillo, Ilana Perelshtein, Maria Tkachev, Olga Girshevitz, Hagay Shpaisman
Abstract
Ωm. Other materials that we studied were found to be porous and prone to cracking, rendering them irrelevant as insulators. Finally, we show how microfluidics can enhance multilayered laser microprinting by quickly switching between precursors. The concepts presented here could provide new opportunities for simple fabrication of multilayered microelectronic devices.
Topics & Concepts
Materials scienceMicroelectronicsFabricationLaserSiliconMicrostructureRaman spectroscopyOxideNanotechnologyTetraethyl orthosilicateOptoelectronicsLayer (electronics)Composite materialOpticsMetallurgyAlternative medicinePathologyPhysicsMedicineLaser Material Processing TechniquesElectrowetting and Microfluidic TechnologiesAdvanced Memory and Neural Computing