Nitrogen Dynamics and Removal by Algal Turf Scrubber under High Ammonia and Organic Matter Loading in a Recirculating Aquaculture System
A study was undertaken to assess the potential of an
Algal Turf Scrubber to remove nitrogen from aquaculture effluent to
reduce environmental pollution. High total ammonia nitrogen
concentrations were introduced to an Algal Turf Scrubber developed
under varying hydraulic surface loading rates of African catfish
(Clarius gariepinus) effluent in a recirculating aquaculture system.
Nutrient removal rates were not affected at total suspended solids
concentration of up to 0.04g TSS/l (P > 0.05). Nitrogen removal
rates 0.93-0.99g TAN/m²/d were recorded at very high loading rates
3.76-3.81 g TAN/m²/d. Total ammonia removal showed ½ order
kinetics between 1.6 to 2.3mg/l Total Ammonia Nitrogen
concentrations. Nitrogen removal increased with its loading, which
increased with hydraulic surface loading rate. Total Ammonia
Nitrogen removal by Algal turf scrubber was higher than reported
values for fluidized bed filters and trickling filters. The algal turf
scrubber also effectively removed nitrate thereby reducing the need
for water exchange.
[1] Smith, V.H. (2003). Euttrophication of freshwater and coastal marine
ecosystems. A global problem. Environ.Sci. & Pollut. Res.10(2), 126-
139.
[2] Sereti, V., L. Sfetcu, H. Huizing, M.C.J. Verdegem, E. Eding and J.A.J.
Verreth, (2005). The potential of a periphyton reactor to maintain thewater quality in recirculating aquaculture systems. Aquaculture and
Fisheries Group, Department of Animal Sciences, Wageningen Institute
of Animal Sciences, Wageningen University and Research Center,
P.O.B. 338, 6700 AH, Wageningen, The Netherlands.
[3] Verdegem, M.C.J., Eding, E.H., Sereti, V., Munubi, R.N., Santacruz-
Reyes and A.A. van Dam (2005). Similarities between microbial and
periphytic biofilms in aquaculture Systems. Aquaculture and Fisheries
Group, Department of Animal Sciences, Wageningen Institute of Animal
Sciences, Wageningen University and Research Center, P.O.B. 338,
6700 AH, Wageningen, The Netherlands.
[4] Parent, S., Morin A., (2000). N budget as water quality management tool
in closed aquatic mesocosms. Water research 34, no. 6, pp.1846-1856.
[5] Huizing, H., (2004). Periphyton reactor for nutrient retention and
maintenance of water quality in recirculating aquaculture system. MSc.
Thesis. Aquaculture and Fisheries Group, Department of Animal
Sciences, Wageningen Institute of Animal Sciences, Wageningen
University and Research Center, P.O.B. 338, 6700 AH, Wageningen,
The Netherlands.
[6] Davis, L.S, Hoffmann, J.P., Cook, P.W. (1990). Production and nutrient
accumulation by periphyton in wastewater treatment facility. J.
Phycol.26, 617-623
[7] Brix, H. and Schierup, H.H. (1989). The use of aquatic macrophytes in
water pollution control. Ambio 18, 101-107.
[8] Korner, S., Vermaat, J.E. and Veenstra, S. (2003). The capacity of
duckweed to treat wastewater: ecological considerations for a sound
design. Journal of Environmental Quality 32, 1583-1590.
[9] Toet, S., Hersbach, L. and Verhoeven, J.T.A. (2003). Periphyton
biomass and nutrient dynamics in a treatment wetland in relation to
substratum, hydraulic retention time and nutrient removal. Archive der
Hydrobiologie-Supplement, 139, 361-392.
[10] APHA (1998). Standard Methods for the examination of water and
wastewater. American Public Health Association, Washington, DC.
[11] Muir, J.F. (1982). Recirculated Water Systems in Aquaculture. In: Muir,
J.F., Roberts, R.J., (Eds), Recent Advances in Aquaculture. Croom
Helm, London, pp. 357-447.
[12] Skjolstrup, J., Nielsen, P.H., Frier, J.O., McLean, E., (1998). Performance
characteristics of fluidized bed bioflters in a novel laboratory-scale
recirculation system for rainbow trout: nitrification rates, oxygen
consumption and sludge collection. Aquacult. Eng. 18, 265-276.
[13] Bovendeur, J. (1989). Fixed-Biofilm reactors applied to wastewater
treatment and aquacultural water recirculating systems. PhD. Thesis,
Wageningen University, Wageningen.
[14] Van Rijn, J., Rivera, G. (1990). Aerobic and anaerobic biofiltration in an
aquaculture unit-Nitrite accumulation as a result of nitrification and
denitrification. Aquacult. Eng. 9, 217-234.
[15] Pizzaro, C., Kebede-Westhead, E., Mulbry, W. 2002. Nitrogen and
phosphorus removal rates using small algal turfs grown with dairy
manure. J. Appli. Phycol. 14, 469-473.
[16] Leclercq, D.I., Hopkins, K. (1985). Preliminary test of an aerated tank
system for tilapia culture. Aquacult. Eng. 4, 229-304.
[17] Ridha, M.T., Cruz, E.M. (2001). Effect of biofilter media on water
quality and biological performance of the Nile Tilapia Oreochromis
niloticus L. reared in a simple recirculation system. Aquacult. Eng. 24,
157-166.
[18] Valeta J.S., (2006). Purification of aquaculture effluents using algal turf
scruber technology. MSc. Thesis. Aquaculture and Fisheries Group,
Department of Animal Sciences, Wageningen Institute of Animal
Sciences, Wageningen University and Research Center, P.O.B. 338,
6700 AH, Wageningen, The Netherlands.
[19] Zhu, S. and Chen, S. (2001). Effects of organic carbon on nitrification
rate in fixed biofilm biofilters. Aquacultural Engineering 25, 1-11.
[20] Syrett, P.J., (1981). Nitrogen metabolism of microalgae. Can. Bull. Fish.
Aquat. Sci. 210, 182-210.
[1] Smith, V.H. (2003). Euttrophication of freshwater and coastal marine
ecosystems. A global problem. Environ.Sci. & Pollut. Res.10(2), 126-
139.
[2] Sereti, V., L. Sfetcu, H. Huizing, M.C.J. Verdegem, E. Eding and J.A.J.
Verreth, (2005). The potential of a periphyton reactor to maintain thewater quality in recirculating aquaculture systems. Aquaculture and
Fisheries Group, Department of Animal Sciences, Wageningen Institute
of Animal Sciences, Wageningen University and Research Center,
P.O.B. 338, 6700 AH, Wageningen, The Netherlands.
[3] Verdegem, M.C.J., Eding, E.H., Sereti, V., Munubi, R.N., Santacruz-
Reyes and A.A. van Dam (2005). Similarities between microbial and
periphytic biofilms in aquaculture Systems. Aquaculture and Fisheries
Group, Department of Animal Sciences, Wageningen Institute of Animal
Sciences, Wageningen University and Research Center, P.O.B. 338,
6700 AH, Wageningen, The Netherlands.
[4] Parent, S., Morin A., (2000). N budget as water quality management tool
in closed aquatic mesocosms. Water research 34, no. 6, pp.1846-1856.
[5] Huizing, H., (2004). Periphyton reactor for nutrient retention and
maintenance of water quality in recirculating aquaculture system. MSc.
Thesis. Aquaculture and Fisheries Group, Department of Animal
Sciences, Wageningen Institute of Animal Sciences, Wageningen
University and Research Center, P.O.B. 338, 6700 AH, Wageningen,
The Netherlands.
[6] Davis, L.S, Hoffmann, J.P., Cook, P.W. (1990). Production and nutrient
accumulation by periphyton in wastewater treatment facility. J.
Phycol.26, 617-623
[7] Brix, H. and Schierup, H.H. (1989). The use of aquatic macrophytes in
water pollution control. Ambio 18, 101-107.
[8] Korner, S., Vermaat, J.E. and Veenstra, S. (2003). The capacity of
duckweed to treat wastewater: ecological considerations for a sound
design. Journal of Environmental Quality 32, 1583-1590.
[9] Toet, S., Hersbach, L. and Verhoeven, J.T.A. (2003). Periphyton
biomass and nutrient dynamics in a treatment wetland in relation to
substratum, hydraulic retention time and nutrient removal. Archive der
Hydrobiologie-Supplement, 139, 361-392.
[10] APHA (1998). Standard Methods for the examination of water and
wastewater. American Public Health Association, Washington, DC.
[11] Muir, J.F. (1982). Recirculated Water Systems in Aquaculture. In: Muir,
J.F., Roberts, R.J., (Eds), Recent Advances in Aquaculture. Croom
Helm, London, pp. 357-447.
[12] Skjolstrup, J., Nielsen, P.H., Frier, J.O., McLean, E., (1998). Performance
characteristics of fluidized bed bioflters in a novel laboratory-scale
recirculation system for rainbow trout: nitrification rates, oxygen
consumption and sludge collection. Aquacult. Eng. 18, 265-276.
[13] Bovendeur, J. (1989). Fixed-Biofilm reactors applied to wastewater
treatment and aquacultural water recirculating systems. PhD. Thesis,
Wageningen University, Wageningen.
[14] Van Rijn, J., Rivera, G. (1990). Aerobic and anaerobic biofiltration in an
aquaculture unit-Nitrite accumulation as a result of nitrification and
denitrification. Aquacult. Eng. 9, 217-234.
[15] Pizzaro, C., Kebede-Westhead, E., Mulbry, W. 2002. Nitrogen and
phosphorus removal rates using small algal turfs grown with dairy
manure. J. Appli. Phycol. 14, 469-473.
[16] Leclercq, D.I., Hopkins, K. (1985). Preliminary test of an aerated tank
system for tilapia culture. Aquacult. Eng. 4, 229-304.
[17] Ridha, M.T., Cruz, E.M. (2001). Effect of biofilter media on water
quality and biological performance of the Nile Tilapia Oreochromis
niloticus L. reared in a simple recirculation system. Aquacult. Eng. 24,
157-166.
[18] Valeta J.S., (2006). Purification of aquaculture effluents using algal turf
scruber technology. MSc. Thesis. Aquaculture and Fisheries Group,
Department of Animal Sciences, Wageningen Institute of Animal
Sciences, Wageningen University and Research Center, P.O.B. 338,
6700 AH, Wageningen, The Netherlands.
[19] Zhu, S. and Chen, S. (2001). Effects of organic carbon on nitrification
rate in fixed biofilm biofilters. Aquacultural Engineering 25, 1-11.
[20] Syrett, P.J., (1981). Nitrogen metabolism of microalgae. Can. Bull. Fish.
Aquat. Sci. 210, 182-210.
@article{"International Journal of Biological, Life and Agricultural Sciences:50067", author = "Joshua S. Valeta and Marc C. Verdegem", title = "Nitrogen Dynamics and Removal by Algal Turf Scrubber under High Ammonia and Organic Matter Loading in a Recirculating Aquaculture System", abstract = "A study was undertaken to assess the potential of an
Algal Turf Scrubber to remove nitrogen from aquaculture effluent to
reduce environmental pollution. High total ammonia nitrogen
concentrations were introduced to an Algal Turf Scrubber developed
under varying hydraulic surface loading rates of African catfish
(Clarius gariepinus) effluent in a recirculating aquaculture system.
Nutrient removal rates were not affected at total suspended solids
concentration of up to 0.04g TSS/l (P > 0.05). Nitrogen removal
rates 0.93-0.99g TAN/m²/d were recorded at very high loading rates
3.76-3.81 g TAN/m²/d. Total ammonia removal showed ½ order
kinetics between 1.6 to 2.3mg/l Total Ammonia Nitrogen
concentrations. Nitrogen removal increased with its loading, which
increased with hydraulic surface loading rate. Total Ammonia
Nitrogen removal by Algal turf scrubber was higher than reported
values for fluidized bed filters and trickling filters. The algal turf
scrubber also effectively removed nitrate thereby reducing the need
for water exchange.", keywords = "Algal turf, loading rate, nitrogen, organic matter, removal rate.", volume = "6", number = "11", pages = "977-8", }
