TY - JOUR
T1 - Surface Charge Reversal Method for High-Resolution Inkjet Printing of Functional Water-Based Inks
AU - Cobas Acosta, R.
AU - Muñoz-Pérez, Susset
AU - Cadogan, Sean
AU - Ridgway, Mark C
AU - Obradors, Xavier
PY - 2015
Y1 - 2015
N2 - Printed electronics is a rapidly growing area of research being explored for the manufacture of large-area and cost-effective electronic devices by the patterned application of functional inks. There are challenges associated with processing the inks compatible with inkjet printing technology and developing efficient methods to successfully obtain the desired features, particularly when it comes to metal and metal-organic complex inks. Here, a reliable method is developed to achieve a sophisticated microstructured pattern using the inkjet printing technique assisted by a surface charge reversal effect. In addition, a procedure is formulated to obtain good quality, stable metal-organic water-based inks compatible with salts of a variety of transition metals and rare earths, without the need for additional volatile solvents. A feasible and water-based ink formulation combined with a simple and noninvasive surface charge reversal treatment constitutes a major step toward the manufacture of high-resolution, inorganic patterned thin films on hydrophobic substrates using inkjet printing. These outcomes lead to the path of effective fusion of inorganic and organic heterointerfaces by simples designing and printing. Surface charge reversal method for high-resolution inkjet printing of functional water-based inks is revealed. The proposed approach modifies the surface energy of hydrophobic substrates by coating with a polyelectrolyte layer in order to overcome dewetting effects as well as to improve adhesion and printing resolution. A suitable metal complex ink is formulated, which can be processed via inkjet printing.
AB - Printed electronics is a rapidly growing area of research being explored for the manufacture of large-area and cost-effective electronic devices by the patterned application of functional inks. There are challenges associated with processing the inks compatible with inkjet printing technology and developing efficient methods to successfully obtain the desired features, particularly when it comes to metal and metal-organic complex inks. Here, a reliable method is developed to achieve a sophisticated microstructured pattern using the inkjet printing technique assisted by a surface charge reversal effect. In addition, a procedure is formulated to obtain good quality, stable metal-organic water-based inks compatible with salts of a variety of transition metals and rare earths, without the need for additional volatile solvents. A feasible and water-based ink formulation combined with a simple and noninvasive surface charge reversal treatment constitutes a major step toward the manufacture of high-resolution, inorganic patterned thin films on hydrophobic substrates using inkjet printing. These outcomes lead to the path of effective fusion of inorganic and organic heterointerfaces by simples designing and printing. Surface charge reversal method for high-resolution inkjet printing of functional water-based inks is revealed. The proposed approach modifies the surface energy of hydrophobic substrates by coating with a polyelectrolyte layer in order to overcome dewetting effects as well as to improve adhesion and printing resolution. A suitable metal complex ink is formulated, which can be processed via inkjet printing.
U2 - 10.1002/adfm.201401638
DO - 10.1002/adfm.201401638
M3 - Article
VL - 25
SP - 768
EP - 775
JO - Advanced Functional Materials
JF - Advanced Functional Materials
IS - 5
ER -