Rf-sputtered ZnO films, annealed by atmospheric pressure plasma jet (APPJ), are characterized and used for MgZnO/ZnO heterostructures. The highly reactive N2 plasma generated by APPJ allows much shorter treatment time compared with conventional thermal anneals. The APPJ treatment can increase the crystallinity of ZnO films and release the compressive residue stresses, verified by XRD and UV–Vis transmission measurements. In our previous studies, we demonstrate that thermal anneal is the critical step for the formation of two-dimensional electron gases in defective rf-sputtered MgZnO/ZnO heterostructures. This thesis reports the experimental results that APPJ treatments can be used for the same purpose with a much shorter processing time. A thirty-second APPJ anneal on ZnO can be used to replace 400 °C × 30 min furnace-anneal to promote the formation of 2DEGs in MgZnO/ZnO heterostructure. The ultra-short processing time is attributed to the synergy of plasma reactivity and temperature of APPJ. This thesis also reports the characterization of sol-gel derived MgZnO thin films converted by APPJs. The MgZnO films exhibit high transparency (> 80%) in the visible light wavelength region. The optical band gap reveals a blue shift as the Mg content increases. The resistivity of the MgxZn1-xO films increases by two to three orders of magnitude for 20% Mg content thin film, owing to the substitution of Mg atoms into the Zn lattice sites. The absorption band edge becomes sharper as the APPJ treatment time increases. This can be attributed to the grain growth of the films. As the grain size is small, the quantum confinement effect causes the slight decrease of the band gap, resulting in the slope alteration at the absorption edge.