Abstract
A systematic investigation of thin films of pyridinium-based ionic liquids (ILs), [C(n)py][NTf(2)] (n = 2-9), deposited via physical vapor deposition on ITO and Au/ITO substrates is presented, providing the first comprehensive study of vacuum-deposited films within this homologous series. The influence of evaporation temperature, deposition rate, alkyl chain length, and substrate on thin-film morphology, nucleation and coalescence dynamics, interfacial behavior, and film structure was examined using SEM, optical microscopy, FTIR, and XPS. SEM analyses reveal that higher evaporation temperatures, which increase the deposition rate, lead to larger droplets and enhanced coalescence, resulting in larger microstructures. A comparison of the film morphologies across the IL series shows that longer cation alkyl chains further enhance lateral spreading and wetting, particularly on Au substrates. An odd-even effect on the morphological characteristics of the films is observed across the series, reflecting subtle differences in interfacial interactions. Moreover, a clear distinction in wetting behavior between short- and long-chain pyridinium ILs is evident, consistent with trends previously reported for imidazolium-based ILs. FTIR spectra comparing bulk and thin IL films confirm that the ILs retain their chemical integrity upon film formation. XPS measurements support the morphological observations, highlighting that ILs comprising longer alkyl chains achieve more complete surface coverage. The results of this work provide fundamental insights into the interplay between the cation alkyl chain length of pyridinium-based ILs, substrate interactions, and film formation dynamics, offering guidance for the rational design of IL films for functional surface applications.