Electrical characteristics and deep level traps study of Au/ZnO:H Schottky diodes

• Published in: Superlattices and microstructures Vol. 75; pp. 171 - 182
• Main Authors: Tsiarapas, Christos, Girginoudi, Dimitra, Georgoulas, Nikolaos
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2014
• Subjects: Au Schottky diodes; Current-transport mechanisms; Deep-level traps; Diodes; Electric potential; Electrical characterization; Gold; Hydrogen; Mathematical models; Schottky diodes; Superlattices; Thermionic emission; Volt-ampere characteristics; ZnO; Deep-level traps; ZnO; Electrical characterization; Current-transport mechanisms; Hydrogen; Au Schottky diodes
• ISSN: 0749-6036; 1096-3677
• DOI: 10.1016/j.spmi.2014.07.041

•Current transport mechanisms-deep levels study of Au Schottky diodes on ZnO:H films.•Thermionic emission in the 33.3% H2 diodes-lateral fluctuations of barrier height.•Trap-assisted current transport mechanisms at the 0%, 20%, 50%, 66.6% H2 diodes.•Two electron traps (0.29 and 0.21eV) related to intrinsic defects.•Higher trap concentrations near the surface and interaction of traps with H2. The electrical characteristics and the deep level traps of Au Schottky contacts on ZnO:H films have been investigated by temperature-dependent current–voltage (I–V) and deep level transient spectroscopy (DLTS) measurements. The films were deposited with the DC-sputtering, varying the H flow rate in the Ar/H sputtering gas, so that the hydrogen per volume concentration [H2] was 0%, 20%, 33.3%, 50% and 66.6%. We found that for the Schottky diodes with [H2]=33.3% thermionic emission is the dominant current transport process at low forward voltage, taking into consideration the lateral fluctuations of the barrier height described by a Gaussian distribution model. The domination of trap-assisted current transport mechanisms is possible in the diodes with [H2]=0%, 20%, 50% and 66.6%. DLTS spectra revealed two electron traps, with activation energies of 0.29 and 0.21eV, often observed in ZnO and related to intrinsic defects. The trap concentrations are significantly lower in the 33.3% H2 diodes compared to the 0% H2 ones, indicating an interaction of these traps with hydrogen.