Results from Tests I, II, and III a

Results from Tests I, II, and III are summarized in
Table 2

3.1. Results for Test I Temporal profiles of biomass, BOD5 and nutrients recorded in
Test I conducted at a typical BOD:N:P ratio (16.5:13.4:1) are shown in Fig. 2
a–d. The cultures grew with minimal lag phase, and reached a maximum density of 1.5 g L 1 in 6 days, by which time,
both N and P had been reduced to negligible levels. On day 3, G. sul-phurariahad achieved maximum growth rate of 0.5 g L 1 d 1 at a density of 1 g L 1, by which time, BOD had been reduced from 60 to 3.7 mg L 1 (>93%), N from 48 to 1.5 mg L 1(>96%), and P from 11 to 0.2 mg L 1 (>98%). The BOD removal rate in this test can be approximated by first order reaction of rate constant = 0.7 d 1(r2= 0.825,
Fig. 2, inset), which is about 50% higher than that of typical activated sludge process (Metcalf et al., 2004).
The volu-metric removals of BOD5, N, and P over the first three days were 18.57, 15.5, and 3.6 mg L 1 d 1, respectively.
During Test I, nutrient uptake preceded the period of maximum growth. More than 90% nutrient removal was achieved by the end of day 3 (Table 2), when only two thirds of the final biomass density
was achieved. This offset between residence time requirements to meet nutrient recovery requirements and maximum biomass den-sity creates a trade-off with respect to operational timing. Maximum energy recovery from UWW requires maximum biomass density but plant capital costs will scale directly with land area
requirement, a function of the hydraulic retention time. Detailed
techno-economicmodelingusingtheremovalrates recordedinthis
study will be required to achieve the desired outcome.