Appl Phys Lett 2004, 85:5185.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions SRJ designed the project of experiments;
performed the XRD, AFM, and nanoindentation analyses; and drafted the manuscript. YCT dealt with the experimental data. HWC and PHC carried out the growth MEK pathway of BFO thin films, and JYJ participated in the paper discussion. All authors read and approved the final manuscript.”
“Background Most research efforts in macroelectronics have opened the door for the manufacture of lightweight, flexible, cost-effective electronic devices that are beyond the conventional silicon-based devices, including flexible displays [1], flexible and conformal antenna arrays [2], electronic solar cell arrays [3], radio-frequency identification tags [4], flexible batteries [5], electronic circuits fabricated in clothing [6], and biomedical devices [7]. Usually, most of them require electrical contacts. Up to now, various materials such as conjugated polymers, graphene, carbon nanotubes, and metals have been used for the preparation of electrodes and conductive patterns using solution processing methods [8–11]. Specifically, metal nanoparticle inks have attracted more Wnt inhibitor and more attention due to their high conductivity and thermal stability after having been sintered [12–14]. However, metallic nanoparticle inks often require
high annealing temperatures (>150°C) to decompose stabilizing agents and other polymeric additives that inhibit electrical conductivity, with the high annealing temperature limiting the choice of substrate. Besides, they Non-specific serine/threonine protein kinase still cannot completely avoid the
condensation and agglomeration of nanoparticles, especially after long-term storage. The agglomerated particles may damage the equipment and influence the printing quality. During preparation, a high-speed centrifuge or vacuum dryer must be used to take nanometal particles out, so these inks cannot be produced on a large scale. All of these will cause a higher production cost [15–18]. There is no surprise to the fact that organic silver conductive ink (OSC ink) has received increasing attention as a potentially much lower cost alternative [19–21]. This kind of ink mainly consists of a silver carrier, weak reduction agent, solvent, and additives, and a continuous conductive silver track can be fabricated during the sintering process. This strategy can compensate for the lack of conductive metal nanoink and thus becomes the development direction of conductive ink for macroelectronics [22–25]. In our previous research, the selleck products relationship between different kinds of amines and ink properties was investigated systematically. The addition of different amines not only increased the solid content of the conductive ink but also decreased the sintering temperature by complexation [26–28].