Abstract
Ph.D.
Thin film photovoltaic modules based on Cu(In,Ga)Se2 (CIGS) thin films possess
attributes that enable them to compete effectively with silicon-based modules. These
attributes are stability, high efficiency, and low material cost. A very promising industrial
related process to produce the chalcopyrite absorber layers involves the selenization of
metallic precursors. However, recent literature suggests that it is extremely difficult to
incorporate an appreciable amount of gallium into the active region of the CIGS thin
film. Regardless of its location in the precursor stack, gallium has been observed to
segregate to the back of the film during the high temperature selenization step.
Consequently, the resulting films are phase-segregated with CuGaSe2 near the Mo
electrode and CuInSe2 at the film surface.
In this study, the incorporation of gallium and sulfur into CuInSe2 thin films was
systematically investigated to establish a scientific and engineering base for the
fabrication of homogeneous CuIn(Se,S)2 and Cu(In,Ga)Se2 quaternary alloys with
optimum band gap values between 1.1 and 1.2 eV. The selenization of seleniumcontaining
(i.e. Cu/InSe, InSe/Cu and InSe/Cu/InSe) precursors in elemental Se vapour
at temperatures around 550°C resulted in CuInSe2 thin films with superior structural
properties. In an attempt to increase the band gap of these films, the selenium species
were replaced by sulfur species during a solid-state diffusion process. Alternatively,
gallium was introduced into the structure by replacing the InSe/Cu/InSe precursors with
InSe/Cu/GaSe precursors. Important process parameters such as the deposition
temperature of precursor elements, the selenization temperature in elemental Se
vapour, as well as the concentration of gallium in the alloys were optimized during
subsequent studies. From these systematic studies optimum experimental conditions
were determined for the deposition of homogeneous Cu(In,Ga)Se2 thin films. The
monophasic nature of the quaternary alloys was confirmed by XRD studies, revealing a
shift in the lattice spacing due to the homogeneous incorporation of gallium into the
chalcopyrite lattice. Completed solar cell devices revealed open-circuit voltages above
500mV, which confirmed the increase in the band gap value of the absorber films.
Professor V. Alberts