Towards effective phosphorus recycling from wastewater: Quantity and quality

Precipitation in the Mg–Ca–NH3–PO4 system has been explored to improve understanding of likely phases recoverable from complex wastewaters. Over a range of Mg/Ca combinations (0–100%) and pH 5–11, at least seven identifiable crystalline phases could be precipitated from artificial wastewater including: struvite, hydroxylapatite, newberyite, brushite, merrilite/whitlockite, octocalcium phosphate, and monetite.This experimental study has outlined the physicochemical conditions required to produce various phosphate products from synthetic wastewater, and found that large differences exist between experimentally formed phases and thermodynamical predictions.Struvite formation is the most desirable precipitate for the recovery of phosphate based upon purity, growth characteristics, dewatering properties, phosphate removal efficiency, and its ability to simultaneously remove ammonia. This study has also demonstrated that in specific cases the preliminary precipitation of brushite is a possible means of decreasing calcium content such that subsequent struvite formation could achieve higher-purity.Utilising experimental results and information on current commodity prices, discussion on the choice of Mg and Ca sources for phosphorus recovery provides guidance on appropriate means to optimise the formation and yield of high quality cost-optimised products.

Graphical abstractFigure optionsDownload full-size imageDownload as PowerPoint slideHighlights► Over seven Mg:Ca:NH4+ phosphates may contribute to P recovered from waste streams. ► Thermodynamics does not accurately predict the co-precipitation of Ca–Mg–P minerals. ► Struvite is the most desirable recovered P product from wastewater. ► The addition of lime or seawater may have financial benefits for total P recovery. ► Precipitation of brushite can remove Ca phosphates prior to struvite precipitation.