Crystallization is one of the first steps during the silicon solar cells value chain. Before silicon solar cells are processed, a silicon ingot is grown either by monocrystalline or multicrystalline processes. During the process, defects may form and impurities may be introduced from several sources.  The distribution of defects and impurities, as well as their interaction, is strongly affected by the crystallization process. Thus crystallization parameters play a key role in determining the final ingots quality. In this presentation, the effect of crystallization parameters on ingot quality and the techniques to assess them are reviewed.

Oxygen is one of the main impurities in Czochralski grown silicon and can in the wrong state cause large problems and reduction in cell efficiency of silicon based solar cells. A large problem is that the recombination activity of the oxygen related defects often increases during cell processing, resulting in a solar cell with much lower cell efficiency than the expected from the as-grown minority carrier lifetime. One reason for this behaviour is believed to be that small oxygen particles can grow during high temperature solar cell processing steps and in this way change their state.

The presentation will discuss the mechanisms for formation of oxygen related defects in monocrystalline silicon and show examples of which heat treatment and characterisation methods that can be used to identify them.

Crystal growth from the melt is the most common process which provides the basic crystalline silicon material for photovoltaic applications. Nowadays main production technologies for producing crystalline silicon are the Czochralski pulling technique, directional solidification and to some extend edge-defined film-fed growth.

As crystal growth equipment and experimentation becomes more and more costly, little room remains for improvements by trial and error procedures. The numerical simulation of crystal growth processes and correlated physical phenomena provides a powerful tool for the crystal grower. Common goals are to improve the material properties at the micro- and macro-scale resulting in higher solar cell efficiency, increase of crystal dimensions and at the same time reducing production costs and time