Abstract :
Exact optical analysis of aluminum doped zinc-oxide (ZnO:Al) thin-films have been shown in [1], as function of reactive O2-and inert N2-gas additions to the inert Ar process-gas. Here, a theoretical model is introduced, which allows the determination of typical semiconductor parameters, by use of UV/Vis/NIR spectroscopy-a contact-free measurement method. In detail, effective dopant concentrations, ne, in semiconducting thin-films, as well as mobilities, μ, drift velocities, vD, lifetimes, τ, and mean free paths, I, of electrons within these layers can be calculated. Sputtered aluminum-doped zinc-oxide (ZnO:Al) thin-films have been analysed with respect to reactive oxygen additions to the inert argon process-gas and with respect to substrate-temperatures. The effects of these two parameters on the above mentioned physical values have been investigated and discussed.
Keywords :
II-VI semiconductors; aluminium; infrared spectra; semiconductor thin films; sputter deposition; ultraviolet spectra; zinc compounds; UV/Vis/NIR spectra; ZnO:Al; aluminum doped zinc-oxide thin-films; contact-free measurement method; drift velocities; effective dopant concentration; inert argon process-gas; mean free paths; optical analysis; reactive oxygen additions; semiconducting thin-films; semiconductor parameters; sputtered thin-films; substrate-temperatures; Absorption; Argon; Conductivity; Dielectric constant; Optical sensors; Photonic band gap; Substrates; Aluminum-doped zinc-oxide (ZnO:Al); UV/Vis/NIR; spectroscopy; transparent conducting oxide (TCO);
