Hydromentia, Inc. (2005) reported i

Hydromentia, Inc. (2005) reported increasing TP removal rates with increasing flow rates, but TP removal rates were based on P water chemistry and not the percent P found in harvested biosolids. The study also did not incorporate any replication to determine if these results were consistent across multiple trials. As a result, further research is necessary to quantify the effect of flow rate on TP removal in algal scrubbers.

Addition of aqueous or solid Ca may improve P removal because Ca-P co-precipitation is an important mechanism of natural P removal in many aquatic ecosystems (Dierberg et al., 2002, Dodds, 2003, Knight et al., 2003, Debusk et al., 2004, White et al., 2006 and Mitsch and Gosselink, 2007). It is also an important removal mechanism in algae scrubber systems (Craggs et al., 1996a, Dodds, 2003 and Debusk et al., 2004). Algae increase water-column pH by removing dissolved carbon dioxide (CO2) during photosynthesis, which promotes co-precipitation of Ca-P. Numerous studies have shown the potential for increased P removal by increasing Ca concentration (Murphy et al., 1983, Carlton and Wetzel, 1988, Kleiner, 1988, Diaz et al., 1994, Danen-Louwerse et al., 1995, Hartley et al., 1997 and Knight et al., 2003). Craggs (2001) theorized that 12-h operation may stabilize Ca-P minerals precipitated during daylight algal photosynthesis, but no work has been done to test the effectiveness of 12-h operation.

The main goal of this research was to investigate methods for increasing TP removal in algae scrubbers. The specific objectives were: (1) assess whether removal is greater under pulsed or continuous inflow, (2) determine the effect of different flow rates, (3) assess if shading helps reduce temperature stress on the algal biomass, (4) establish whether influent P concentration affects TP removal, (5) determine if aqueous or solid Ca addition affects TP removal rates, and (6) establish whether Ca-P precipitates are stable during diurnal pH shifts.