Development of Gold Inks for Inkjet Printing of Gas Sensors Electrodes on Plastic Support

Among the conventional inks used for inkjet printing, metals, oxides, or polymers have been deposited in order to form functional coatings. Gold is one of the most used metals for electrode fabrication in the gas sensor field due to its inert behavior when exposed to reactive gases and conductive pr...

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Veröffentlicht in:	Electronics (Basel) 2024-06, Vol.13 (11), p.2110
Hauptverfasser:	Le Porcher, Bastien, Rieu, Mathilde, Viricelle, Jean-Paul
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Sprache:	eng
Schlagworte:	Annealing Aqueous solutions Chemical and Process Engineering Electrodes Engineering Sciences Gas sensors Gold Gold coatings Inkjet printing Inks Metal oxides Methods Nanoparticles Sensors Silicon wafers Silver Surface tension Temperature Viscosity
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creator	Le Porcher, Bastien Rieu, Mathilde Viricelle, Jean-Paul
description	Among the conventional inks used for inkjet printing, metals, oxides, or polymers have been deposited in order to form functional coatings. Gold is one of the most used metals for electrode fabrication in the gas sensor field due to its inert behavior when exposed to reactive gases and conductive properties. However, only a few commercial gold inks are commercially available, and the combination of excessive price, a high minimum purchase quantity, and an unknown composition renders the actual products unappealing. To meet these shortcomings, gold inks were formulated with different solvents in order to reach sufficient properties for the inkjet printing process, such as surface tension and viscosity. On the one hand, gold ink was developed using a gold nanoparticle (AuNP) solution as the metal. This ink was optimized from nanoparticle synthesis, with the ink formulation obtaining a 32 mN·m−1 surface tension and 11.2 mPa·s viscosity in order to be inkjet-printed onto polyimide foil. On the other hand, a particle-free ink, called a precursor based of ink, was also developed. In this case, ink was made by solubilizing gold salt in aqueous medium in order to reach jettable properties. Surface tension was measured at 32 mN·m−1 while viscosity was 14.0 mPa·s. Then, printing and deposition parameters were optimized in order to obtain a highly conductive gold coating. The measured resistivity was 2 × 10−7 Ω·m which is close to the bulk gold conductive value. These coatings could be used for the fabrication of various devices in different working fields.
doi_str_mv	10.3390/electronics13112110
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In this case, ink was made by solubilizing gold salt in aqueous medium in order to reach jettable properties. Surface tension was measured at 32 mN·m−1 while viscosity was 14.0 mPa·s. Then, printing and deposition parameters were optimized in order to obtain a highly conductive gold coating. The measured resistivity was 2 × 10−7 Ω·m which is close to the bulk gold conductive value. 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subjects	Annealing Aqueous solutions Chemical and Process Engineering Electrodes Engineering Sciences Gas sensors Gold Gold coatings Inkjet printing Inks Metal oxides Methods Nanoparticles Sensors Silicon wafers Silver Surface tension Temperature Viscosity
title	Development of Gold Inks for Inkjet Printing of Gas Sensors Electrodes on Plastic Support
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