Additive-free silver nanoparticle ink development using flow-based Laser Ablation Synthesis in Solution and Aerosol Jet printing Article Swipe

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Materials science Inkwell Aerosol Laser ablation Printed electronics Electrical resistivity and conductivity Nanotechnology Electrical conductor Electronics Particle (ecology) Nanoparticle Composite material Laser Optics Chemistry Electrical engineering Geology Physics Engineering Physical chemistry Organic chemistry Oceanography

Sithara P. Sreenilayam , Éanna McCarthy , Lorcan McKeon , Oskar Ronan , R. McCann , K. Fleischer , Brian Freeland , Valeria Nicolosi , Dermot Brabazon ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.1016/j.cej.2022.137817 · OA: W4293145369

Additive free conductive ink formulation via green techniques and its direct printing is critical for many applications including smart electronics, solar cells, healthcare and electrochemical energy storage. The available printable ink generations are far away from ideal. This study reports the development of additive free silver (Ag) nano particle (NP) inks via flow-based Laser Ablation Synthesis in Solution (LASiS) system and Aerosol Jet printing. Examples of LASiS Ag NP printed tracks and patterns on unprocessed glass, rubber, and plastic substrates with spatial uniformity and high printing resolution are demonstrated. For thermally sintered Ag NP track, the resistivity decreased to 4.74 × 10−6 Ω m and conductivity improved to 2.11 × 105 S/m. The track resistance of ≈ 83 Ω improved to ≈ 51 Ω and the resistivity of 7.72 10−6 Ω m (conductivity: 1.29 × 105 S/m) improved to 4.74 × 10−6 Ω m. This work highlights that LASiS is a versatile, additive-free conductive ink formulation method for the scalable production of next generation printed electronic components and devices, using the emerging Aerosol Jet printing technology.