In contrast, as shown in Figure 4c, the in situ QNZ molecular weight sintered conductive pattern revealed a continuous silver track with less pores or voids. This was due to the Marangoni flow that

facilitated the silver nanoparticles to spread and join large liquid nanoparticles and promote the evaporation of surfactant during the in situ sintering process accordingly [41]. In this case, even a low sintering temperature (140°C) could allow the patterns to be conductive with R sq of 6 Ω/cm2. Figure 4 Metallurgical microscope INK1197 mw and SEM images of silver patterns and EDS analysis. Metallurgical microscope images of silver patterns: (a) inkjet-printed and (b) spray-coated patterns with 170°C post sintering and (c) spray-coated patterns with 170°C in situ sintering. SEM images of the morphology of spray-coated silver

patterns based on 170°C post sintering (d) and in situ sintering (e) processes. (f, g) EDS analysis of the dark bulges and flattened area in (d, e), respectively. Furthermore, SEM was employed to understand the change in the morphology of spray-coated silver nanoparticle inks. Figure 4d,e shows the morphology of spray-coated post sintered and in situ sintered conductive patterns, respectively. In Enzalutamide chemical structure Figure 4d, it is obvious that there are a large number of nanoscale dark bulges on the surface of post sintered patterns, and the surface roughness is about 40 nm. However, in situ sintered patterns significantly exhibit

a lower density of dark bulges. Additionally, in situ sintered patterns exhibit a smoother surface with a roughness of 23 nm. Characterized by EDS, a detailed elemental analysis of the sample Ribonuclease T1 has been performed. The dark bulges were corresponding to the C element peaking at 0.3 keV. The flat surface was related to the binding energies of Ag L α and Ag L β at the peaks of 3.0 and 3.2 keV, respectively [42]. The main reason for dense dark bulges in the post sintered pattern was that there was a large space for the stabilizer polymer to transfer to the surface and aggregate to become bulges during sintering at high temperature [41]. In comparison, the relatively sparse dark bulges of the in situ sintered pattern can be attributed to the simultaneous evaporation of the stabilizer polymer and sintering of silver inks. Dried droplet limited the mobility of the stabilizer polymer, which was not affected by the latish wet droplet inks. Hence, there were a few dark bulges detected on the surface, but many of them were distributed into the whole pattern vertically. This was also consistent with the lower conductivity of in situ sintered conductive patterns at high sintering temperature [40]. To testify the application of spray-coated silver nanoparticle inks for optoelectronic application, an inverted PSC was fabricated.