Abstract

This work reports a detailed study on the low-temperature synthesis of highly conductive transparent Al-doped ZnO films using magnetron sputtering with the support of an inductively coupled plasma (ICP) source. It is seen that the ICP source is quite useful to provide significant ionization and excitation reactions conducive to the film growth in the magnetron plasmas. The effect of different plasma parameters on the film properties is investigated in detail. Data reveal that tailoring of vacancies of oxygen and extrinsic dopants (Al0 and Al3+) and plasma chemistry in high electron density discharges could provide simultaneous enrichment in the carriers' mobility and concentration. A plausible mechanism involving the correlation between the carrier mobility and the electron-hole interaction is realized for degenerately doped wide bandgap semiconductors.