Potential use of zero-valent iron in enhancing performance and resource recovery during the anaerobic digestion of domestic sewage
Abstract
Incorporating metallic iron (Fe
0
) into anaerobic digesters can improve organics (chemical
oxygen demand (COD)), phosphorus, and nitrogen from contaminated water. However, no
study has systematically assessed Fe0
-supported anaerobic digestion (AD) systems for
removing organic compounds and nutrients from domestic sewage (DS), limiting our
understanding of their potential to replace tertiary treatment units. Besides, existing studies
often focus on single contaminants at high concentrations, which may not reflect real-world
effluents with multiple pollutants. Variations in experimental conditions and the type of
wastewater effluent treated complicate comparisons across studies. Additionally, there is a lack
of comprehensive evaluations of predictive models for methane (CH₄) yields in Fe0
-supported
AD systems, hindering the identification of the most effective model and affecting future
research and applications. Moreover, there is little information on sludge characteristics from
Fe0
-aided AD systems and their potential applications. This research focused on three primary
objectives: (i) assessing the impact of Fe0
type and dosage in AD systems for the simultaneous
removal of COD and nutrients (orthophosphate (PO4
3-
), ammonium (NH4
+
), nitrate (NO3
-
)),
and (ii) characterizing the solids and biogas in Fe0
-supported AD of DS, and (iii) evaluating
the Gompertz, Logistic, and Richard models for methane yield prediction. Two distinct
experiments were conducted at various scales. In the first experiment, lab-scale reactors
containing DS were subjected to varying dosages of Fe0
(0 to 30 g/L) over 32 experimental
runs conducted for 76 days at a constant temperature of 37 ± 0.5℃. In the second experiment,
bench-scale reactors with DS were fed with Fe0 and operated over 15 experimental runs for 53
days at 24 ± 3℃ temperature. Iron scraps (SI) and steel wool (SW) were used as the Fe0
sources.
A control experiment was also conducted. It was found out that: (a) the optimal Fe0
dosage for
organic and nutrient removal was 10 g/L SI, (b) NH4
+
and NO3
-
removal showed the lowest
removal efficiency, and (c) maximum removal efficiencies for COD, PO4
3-
, and NH4
+ + NO3
-
were 88.0%, 98.0%, and 40.0% for 10 g/L SI; 88.2%, 99.9%, and 25.1% for 10 g/L SW; and
68.9%, 7.3%, and 0.7% for the control system. Fe0
significantly enriched nutrients in the
sludge, improved settling characteristics, and increased the percentage of methane content in
biogas by over 12%. All tested methane prediction models showed good accuracy (error <
10%), with the Richard model demonstrating the highest level of fit (error < 1.6%). These
findings confirm the effectiveness of Fe0
-supported AD in removing organics and nutrients
from DS, producing agriculturally suitable sludge, and enhancing biogas methane content for
potential energy recovery