and have been observed by other aut

and have been observed by other authors (Babić-Ivančić et al., 2002, 2006; Prywer et al., 2012; Rouff, 2013). Prywer et al. (2012) stated that dendritic structures appear when the system under- goes rapid pH changes. In this study, MgCl2 experiments were maintained at a constant pH, and the temporary decrease in pH was caused by rapid struvite formation until this was balanced by titrating NaOH into the system (Fig. 6). Thus, dendrites inherit from of a highly supersaturated solution that is created by adding large amounts of magnesia (initial Mg:P values) in combination with basic pH values. This phenomenon supports the findings of Babić-Ivančić et al. (2002).
Contrary to the MgCl2 runs, dendritic and fern-leaf-shaped crystals are observed for all MgO products (Fig. 9, top row). Fig. 10 shows a micrograph of a sample taken 40 s after the addition of the MgO suspension, showing a small dendritic crystal growing on the surface of a magnesia particle. EDX analysis showed that the crystalline structure is most likely struvite. It is assumed that the MgO particles of the suspension, with their Mg(OH)2 layer, facilitate heterogeneous nucleation. Furthermore, the mechanism of MgO/Mg(OH)2 dissolution may lead to high local concentrations of Mg2þ and OH ions around the porous particle. In combination with NH4þ and PO34  , this local area is highly supersaturated. This offers ideal conditions for fast crystal formation, which eventually leads to dendritic growth and smaller particle sizes. On the other hand, Fig. 5 shows the same behavior for all Mg:P ratios, and the rates of struvite precipitation do not appear to be influenced by the amount of suspended particles. Heterogeneous nucleation would cause increased struvite formation with additional surfaces added to the system at higher Mg:P ratios. In addition, the system is well agitated, which should reduce the supersaturated layer around the suspended particles to a negligible size. Further experi- ments are required to identify the nucleation mechanism and to clarify the role of an elevated Mg2 þ concentration around the suspended particles. Nevertheless, the large amounts of magnesia solids seem to strongly influence the precipitation process.
Fig. 10. Struvite growing on the surface of a MgO particle.
4. Conclusion
The MgO dissolution experiments show that the preparation of the MgO suspension is actually a very effective hydration process, and is due to a MgO dissolution and Mg(OH)2 precipitation step. As a result, more than 99% of the initial MgO is converted into Mg(OH)2. Never- theless, the MgO suspension is reproducible and useful as a struvite precipitation precursor, when prepared 8–16 h before usage.
Struvite precipitation occurs within the first minutes of the process, and comprises MgO/Mg(OH)2 dissolution and struvite precipitation. All investigated Mg:P molar ratios show the same characteristics of fast precipitation, instant nucleation, dendritic growth and small crystal sizes. The results are typical for experi- ments with a homogenous MgCl2 solution as a precursor at high supersaturation levels (Mg:P 1). An explanation for the observed behavior might be found in the local chemistry around the suspended magnesia particles. The suspension has a great impact