Advanced search
Publication Cover
Critical Reviews in Environmental Science and Technology Volume 46, 2016 - Issue 10
Submit an article Journal homepage
1,092
Views
84
CrossRef citations to date
0
Altmetric
Articles

Chemicals used for in situ immobilization to reduce the internal phosphorus loading from lake sediments for eutrophication control

Changhui WangState Key Laboratory of Lake Science and Environment, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing, China
&
He-Long JiangState Key Laboratory of Lake Science and Environment, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing, ChinaCorrespondence[email protected]
Pages 947-997 | Published online: 15 Jun 2016

References

  • Agyin-Birikorang, S., and O'Connor, G. A. (2007). Lability of drinking water treatment residuals (WTR) immobilized phosphorus: Aging and pH effects. Journal of Environmental Quality, 36, 1076–1085.
  • Ahlgren, J., Tranvik, L., Gogoll, A., Waldeback, M., Markides, K., and Rydin, E. (2005). Sediment depth attenuation of biogenic phosphorus compounds measured by 31P NMR. Environmental Science & Technology, 39, 867–872.
  • Akhurst, D., Jones, G. B., and McConchie, D. M. (2004). The application of sediment capping agents on phosphorus speciation and mobility in a sub-tropical dunal lake. Marine and Freshwater Research, 55, 715–725.
  • Andersen, F. ∅., and Ring, P. (1999). Comparison of phosphorus release from littoral and profundal sediments in a shallow, eutrophic lake. Hydrobiologia, 408, 175–183.
  • Anderson, M. A. (2004a). Impacts of metal salt addition on the chemistry of Lake Elsinore, California: 1. Alum. Lake and Reservoir Management, 20, 249–258.
  • Anderson, M. A. (2004b). Impacts of metal salt addition on water chemistry of Lake Elsinore, California: 2. Calcium salts. Lake and Reservoir Management, 20, 270–279.
  • Anderson, M. A., and Berkowitz, J. (2010). Aluminum polymers formed following alum treatment of lake water. Chemosphere, 81, 832–836.
  • Australian and New Zealand Environment and Conservation Council. (2000). Australian and New Zealand guidelines for fresh and marine water quality. National Water Quality Management Strategy Paper No 4. Canberra, Australia: ANZECC & Agriculture and Resource Management Council of Australia and New Zealand.
  • Auvray, F., van Hullebusch, E. D., Deluchat, V., and Baudu, M. (2006). Laboratory investigation of the phosphorus removal (SRP and TP) from eutrophic lake water treated with aluminium. Water Research, 40, 2713–2719.
  • Babatunde, A. O., and Zhao, Y. Q. (2007). Constructive approaches towards water treatment works sludge management: An international review of beneficial reuses. Critical Reviews in Environmental Science and Technology, 37, 129–164.
  • Babin, J., Prepas, E. E., Murphy, T. P., and Hamilton, H. R. (1989). A test of the effects of lime on algal biomass and total phosphorus concentrations in Edmonton stormwater retention lakes. Lake and Reservoir Management, 5, 129–135.
  • Babin, J., Prepas, E. E., Murphy, T. P., Serediak, M., Curtis, P. J., Zhang, Y., and Chambers, P. A. (1994). Impact of lime on sediment phosphorus release in hard water lakes: The case of hypereutrophic Halfmoon Lake, Alberta. Lake and Reservoir Management, 8, 131–142.
  • Barko, J. W., James, W. F., Taylor, W. D., and McFarland, D. G. (1990). Effects of alum treatment on phosphorus and phytoplankton dynamics in Eau Galle Reservoir: A synopsis. Lake and Reservoir Management, 6, 1–8.
  • Barry, M. J., and Meehan, B. J. (2000). The acute and chronic toxicity of lanthanum to Daphnia carinata. Chemosphere, 41, 1669–1674.
  • Berg, U., Neumann, T., Donnert, D., Nuesch, R., and Stüben, D. (2004). Sediment capping in eutrophic lakes - efficiency of undisturbed calcite barriers to immobilize phosphorus. Applied Geochemistry, 19, 1759–1771.
  • Berkowitz, J., Anderson, M. A., and Amrhein, C. (2006). Influence of aging on phosphorus sorption to alum floc in lake water. Water Research, 40, 911–916.
  • Berkowitz, J., Anderson, M. A., and Graham, R. C. (2005). Laboratory investigation of aluminum solubility and solid-phase properties following alum treatment of lake waters. Water Research, 39, 3918–3928.
  • Bi, L. J., Yang, J., and Sun, S. Q. (2012). Study on phosphorus release from sediment control by in-situ control technology. Advanced Materials Research, 374, 899–904.
  • Bishop, W. M., McNabb, T., Cormican, I., Willis, B. E., and Hyde, S. (2014). Operational evaluation of Phoslock phosphorus locking technology in Laguna Niguel Lake, California. Water Air Soil Pollution, 225, 2018.
  • Boers, P., Van der Does, J., and Quaak, M. (1992). Fixation of phosphorus in lake-sediments using iron(III) chloride-experiences, expectations. Hydrobiologia, 233, 211–212.
  • Boström, B., and Pettersson, K. (1982). Different patterns of phosphorus release from lake sediments in laboratory experiments. Hydrobiologia, 91, 415–429.
  • Boyer, T. H., Persaud, A., Banerjee, P., and Palomino, P. (2011). Comparison of low-cost and engineered materials for phosphorus removal from organic-rich surface water. Water Research, 45 (16), 4803–4814.
  • Buergel, P. M., and Soltero, R. A. (1983). The distribution and accumulation of aluminum in rainbow trout following a whole-lake alum treatment. Journal of Freshwater Ecology, 2, 37–44.
  • Bulson, P. C., Johnstone, D. L., Gibbons, H. L., and Funk, W. H. (1984). Removal and inactivation of bacteria during alum treatment of a lake. Applied and Environmental Microbiology, 48, 425–430.
  • Burley, K. L., Prepas, E. E., and Chambers, P. A. (2001). Phosphorus release from sediments in hardwater eutrophic lakes: the effects of redox-sensitive and -insensitive chemical treatments. Freshwater Biology, 46, 1061–1074.
  • Butkus, M. A., Grasso, D., Schulthess, C. P., and Wijnja, H. (1998). Surface complexation modeling of phosphate adsorption by water treatment residual. Journal of Environmental Quality, 27, 1055–1063.
  • Caraco, N. F., Cole, J. J., and Likens, G. E. (1989). Evidence for sulfate-controlled phosphorus release from sediments of aquatic systems. Nature, 341, 316–318.
  • Carpenter, S. R. (2008). Phosphorus control is critical to mitigating eutrophication. Proceedings of the National Academy of Sciences of the United States of Ameirca, 105, 11039–11040.
  • Chai, B. B., Huang, T. L., Zhu, W. H., and Yang, F. Y. (2011). A new method of inhibiting pollutant release from source water reservoir sediment by adding chemical stabilization agents combined with water-lifting aerator. Journal of Environmental Sciences-China, 23, 1977–1982.
  • Chambers, P. A., Prepas, E. E., Ferguson, M. E., Serediak, M., Guy, M., and Holst, M. (2001). The effects of lime addition on aquatic macrophytes in hard water: In situ and microcosm experiments. Freshwater Biology, 46, 1121–1138.
  • Chang, M. Y., and Juang, R. S. (2004). Adsorption of tannic acid, humic acid, and dyes from water using the composite of chitosan and activated clay. Journal of Colloid and Interface Science, 278, 18–25.
  • Chen, M., Ye, T. R., Krumholz, L. R., and Jiang, H. L. (2014). Temperature and cyanobacterial bloom biomass influence phosphorus cycling in eutrophic lake sediments. PLoS One, 9, 1–10.
  • Chen, Y. X., Zhu, G. W., Tian, G. M., and Chen, H. L. (2003). Phosphorus and copper leaching from dredged sediment applied on a sandy loam soil: Column study. Chemosphere, 53, 1179–1187.
  • Christophoridis, C., and Fytianos, K. (2006). Conditions affecting the release of phosphorus from surface lake sediments. Journal of Environmental Quality, 35, 1181–1192.
  • Clearwater, S. J., Hickey, C. W., and Thompson, K. J. (2014). The effect of chronic exposure to phosphorus-inactivation agents on freshwater biota. Hydrobiologia, 728, 51–65.
  • Connor, J. N., and Martin, M. R. (1989). An assessment of sediment phosphorus inactivation, Kezar Lake, New Hampshire. JAWRA Journal of the American Water Resources Association, 25, 845–853.
  • Cooke, G. D., Heath, R. T., Kennedy, R. H., and Mccomas, M. R. (1982). Change in lake trophic state and internal phosphorus release after aluminum sulfate application. JAWRA Journal of the American Water Resources Association, 18, 699–705.
  • Cooke, G. D., Welch, E. B., Martin, A. B., Fulmer, D. G., Hyde, J. B., and Schrieve, G. D. (1993). Effectiveness of Al, Ca, and Fe Salts for Control of Internal Phosphorus Loading in Shallow and Deep Lakes. Hydrobiologia, 253, 323–335.
  • Cottingham, K. L., Ewing, H. A., Greer, M. L., Carey, C. C., and Weathers, K. C. (2015). Cyanobacteria as biological drivers of lake nitrogen and phosphorus cycling. Ecosphere, 6, article 1.
  • Crosa, G., Yasseri, S., Nowak, K. E., Canziani, A., Roella, V., and Zaccara, S. (2013). Recovery of Lake Varese: Reducing trophic status through internal P load capping. Fundamental and Applied Limnology/Archiv für Hydrobiologie, 183, 49–61.
  • Dai, G., Zhong, J., Song, L., Guo, C., Gan, N., and Wu, Z. (2015). Harmful algal bloom removal and eutrophic water remediation by commercial nontoxic polyamine-co-polymeric ferric sulfate-modified soils. Environmental Science and Pollution Research, 22, 10636–10646.
  • Dai, L. C., and Pan, G. (2014). The effects of red soil in removing phosphorus from water column and reducing phosphorus release from sediment in Lake Taihu. Water Science and Technology, 69, 1052–1058.
  • Dayton, E. A., and Basta, N. T. (2005). A method for determining the phosphorus sorption capacity and amorphous aluminum of aluminum-based drinking water treatment residuals. Journal of Environmental Quality, 34, 1112–1118.
  • De Vicente, I., Huang, P., Andersen, F. ∅., Jensen, H. S. (2008a). Phosphate adsorption by fresh and aged aluminum hydroxide. Consequences for lake restoration. Environmental Science & Technology, 42, 6650–6655.
  • De Vicente, I., Jensen, H. S., Andersen, F. ∅. (2008b). Factors affecting phosphate adsorption to aluminum in lake water: Implications for lake restoration. Science of the Total Environment, 389, 29–36.
  • DeGasperi, C. L., Spyridakis, D. E., and Welch, E. B. (1993). Alum and nitrate as controls of short-term anaerobic sediment phosphorus release: An in vitro comparison. Lake and Reservoir Management, 8, 49–59.
  • Deppe, T., and Benndorf, J. (2002). Phosphorus reduction in a shallow hypereutrophic reservoir by in-lake dosage of ferrous iron. Water Research, 36, 4525–4534.
  • Ding, Y. Q., Qin, B. Q., Hu, H., Dong, B. L., and Brookes, D. J. (2012). Comparison of efficacy of two P-inactivation agents on sediments from different regions of Lake Taihu: Sediment core incubations. Fundamental and Applied Limnology / Archiv für Hydrobiologie, 181, 271–281.
  • Dittrich, M., Dittrich, T., Sieber, I., and Koschel, R. (1997). A balance analysis of phosphorus elimination by artificial calcite precipitation in a stratified hardwater lake. Water Research, 31, 237–248.
  • Dittrich, M., Gabriel, O., Rutzen, C., and Koschel, R. (2011). Lake restoration by hypolimnetic Ca (OH)2 treatment: Impact on phosphorus sedimentation and release from sediment. Science of the Total Environment, 409, 1504–1515.
  • Dittrich, M., and Koschel, R. (2002). Interactions between calcite precipitation (natural and artificial) and phosphorus cycle in the hardwater lake. Hydrobiologia, 469, 49–57.
  • Dithmer, L., Lipton, A. S., Reitzel, K., Warner, T. E., Lundberg, D., and Nielsen, U. G. (2015). Characterization of phosphate sequestration by a lanthanum modified bentonite clay: A solid-state NMR, EXAFS, and PXRD study. Environmental Science & Technology, 49, 4559–4566.
  • Douglas, G. B. (2002). Remediation material and remediation process for sediments. U.S. Patent 6350383.
  • Dugopolski, R. A., Rydin, E., and Brett, M. T. (2008). Short-term effects of a buffered alum treatment on Green Lake sediment phosphorus speciation. Lake and Reservoir Management, 24, 181–189.
  • Egemose, S., de Vicente, I., Reitzel, K., Flindt, M. R., Andersen, F. ∅., Lauridsen, T. L., Søndergaard, M., Jeppesen, E., and Jensen, H. S. (2011). Changed cycling of P, N, Si, and DOC in Danish Lake Nordborg after aluminum treatment. Canadian Journal of Fisheries and Aquatic Sciences, 68, 842–856.
  • Egemose, S., Reitzel, K., Andersen, F. ∅., and Flindt, M. R. (2010). Chemical lake restoration products: Sediment stability and phosphorus dynamics. Environmental Science & Technology, 44, 985–991.
  • Egemose, S., Reitzel, K., Andersen, F. ∅., and Jensen, H. S. (2013). Resuspension-mediated aluminium and phosphorus distribution in lake sediments after aluminium treatment. Hydrobiologia, 701, 79–88.
  • Egemose, S., Wauer, G., and Kleeberg, A. (2009). Resuspension behaviour of aluminium treated lake sediments: Effects of ageing and pH. Hydrobiologia, 636, 203–217.
  • Elkhatib, E. A., Mahdy, A. M., and ElManeah, M. M. (2013). Effects of drinking water treatment residuals on nickel retention in soils: A macroscopic and thermodynamic study. Journal of Soils and Sediments, 13, 94–105.
  • Engstrom, D. R. (2005). Long-term changes in iron and phosphorus sedimentation in Vadnais Lake, Minnesota, resulting from ferric chloride addition and hypolimnetic aeration. Lake and Reservoir Management, 21, 96–106.
  • Foy, R. H. (1985). Phosphorus inactivation in a eutrophic lake by the direct addition of ferric aluminum sulfate: impact on iron and phosphorus. Freshwater Biology, 15, 613–629.
  • Foy, R. H. (1986). Suppression of phosphorus release from lake-sediments by the addition of nitrate. Water Research, 20, 1345–1351.
  • Francko, D. A., and Heath, R. T. (1981). Aluminum sulfate treatment – Short-term effect on complex phosphorus-compounds in a eutrophic lake. Hydrobiologia, 78, 125–128.
  • Gächter, R., Meyer, J. S., and Mares, A. (1988). Contribution of bacteria to release and fixation of phosphorus in lake sediments. Limnology and Oceanography, 33, 1542–1558.
  • Gächter, R., and Müller, B. (2003). Why the phosphorus retention of lakes does not necessarily depend on the oxygen supply to their sediment surface. Limnology and Oceanography, 48, 929–933.
  • Gallepp, G. W. (1979). Chironomid influence on phosphorus release in sediment-water microcosms. Ecology, 60, 547–556.
  • Galvez-Cloutier, R., Saminathan, S. K. M., Boillot, C., Triffaut-Bouchet, G., Bourget, A., and Soumis-Dugas, G. (2012). An evaluation of several in-lake restoration techniques to improve the water quality problem (eutrophication) of Saint-Augustin Lake, Quebec, Canada. Environmental Management, 49, 1037–1053.
  • Gardner, W. S., Nalepa, T. F., Quigley, M. A., and Malczyk, J. M. (1981). Release of phosphorus by certain benthic invertebrates. Canadian Journal of Fisheries and Aquatic Sciences, 38, 978–981.
  • Ghadouani, A., Alloul, B. P., and Zhang, Y. (1998). Relationships between zooplankton community structure and phytoplankton in two lime-treated eutrophic hardwater lakes. Freshwater Biology, 39, 775–790.
  • Gibbons, M. K., and Gagnon, G. A. (2011). Understanding removal of phosphate or arsenate onto water treatment residual solids. Journal of Hazardous Materials, 186, 1916–1923.
  • Gibbs, M. M., Hickey, C. W., and Özkundakci, D. (2011). Sustainability assessment and comparison of efficacy of four P-inactivation agents for managing internal phosphorus loads in lakes: sediment incubations. Hydrobiologia, 658, 253–275.
  • Gibbs, M. M., and Özkundakci, D. (2011). Effects of a modified zeolite on P and N processes and fluxes across the lake sediment-water interface using core incubations. Hydrobiologia, 661, 21–35.
  • Gołdyn, R., Podsiadłowski, S., Dondajewska, R., and Kozak, A. (2014). The sustainable restoration of lakes—towards the challenges of the Water Framework Directive. Ecohydrology & Hydrobiology, 14, 68–74.
  • Granéli, W., and Solander, D. (1988). Influence of aquatic macrophytes on phosphorus cycling in lakes. Hydrobiologia, 170, 245–266.
  • Grochowska, J. K., and Brzozowska, R. (2013). The influence of different recultivation methods on the water buffer capacity in a degraded urban lake. Knowledge and Management of Aquatic Ecosystems, 410, 01.
  • Gunn, I. D., Meis, S., Maberly, S. C., and Spears, B. M. (2013). Assessing the responses of aquatic macrophytes to the application of a lanthanum modified bentonite clay, at Loch Flemington, Scotland, UK. Hydrobiologia, 737, 309–320.
  • Gustavson, K. E., Burton, G. A., Francingues, N. R., Reible, D. D., Vorhees, D. J., and Wolfe, J. R. (2008). Evaluating the effectiveness of contaminated-sediment dredging. Environmental Science & Technology, 42, 5042–5047.
  • Hamilton, S. K., Bruesewitz, D. A., Horst, G. P., Weed, D. B., and Sarnelle, O. (2009). Biogenic calcite-phosphorus precipitation as a negative feedback to lake eutrophication. Canadian Journal of Fisheries and Aquatic Sciences, 66, 343–350.
  • Han, J., Jeon, B. S., Futatsugi, N., and Park, H. D. (2013). The effect of alum coagulation for in-lake treatment of toxic Microcystis and other cyanobacteria related organisms in microcosm experiments. Ecotoxicology and Environmental Safety, 96, 17–23.
  • Hansen, J., Reitzel, K., Jensen, H. S., and Andersen, F. ∅. (2003). Effects of aluminum, iron, oxygen and nitrate additions on phosphorus release from the sediment of a Danish softwater lake. Hydrobiologia, 492, 139–149.
  • Hart, B. T., Roberts, S., James, R., O'Donohue, M., Taylor, J., Donnert, D., Furrer, R. (2003b). Active barriers to reduce phosphorus release from sediments: Effectiveness of three forms of CaCO3. Australian Journal of Chemistry, 56, 207–217.
  • Hart, B., Roberts, S., James, R., Taylor, J., Donnert, D., Furrer, R. (2003a). Use of active barriers to reduce eutrophication problems in urban lakes. Water Science and Technology, 47, 157–163.
  • Hartikainen, H., Pitkänen, M., Kairesalo, T., and Tuominen, L. (1996). Co-occurrence and potential chemical competition of phosphorus and silicon in lake sediment. Water Research, 30, 2472–2478.
  • Hartley, A. M., House, W. A., Callow, M. E., and Leadbeater, B. S. C. (1997). Coprecipitation of phosphate with calcite in the presence of photosynthesizing green algae. Water Research, 31, 2261–2268.
  • Herdendorf, C. E. (1982). Large lakes of the world. Journal of Great Lakes Research, 8, 379–412.
  • Higgins, B. P. J., Mohleji, S. C., and Irvine, R. L. (1976). Lake treatment with fly-ash, lime, and gypsum. Journal (Water Pollution Control Federation), 48, 2153–2164.
  • Holdren, G. C., and Armstrong, D. E. (1980). Factors affecting phosphorus release from intact lake sediment cores. Environmental Science & Technology, 14, 79–87.
  • Holz, J. C., and Hoagland, K. D. (1999). Effects of phosphorus reduction on water quality: Comparison of alum-treated and untreated portions of a hypereutrophic lake. Lake and Reservoir Management, 15, 70–82.
  • Horppila, J., and Nurminen, L. (2003). Effects of submerged macrophytes on sediment resuspension and internal phosphorus loading in Lake Hiidenvesi (southern Finland). Water research, 37, 4468–4474.
  • Hovsepyan, A., and Bonzongo, J. C. J. (2009). Aluminum drinking water treatment residuals (Al-WTRs) as sorbent for mercury: Implications for soil remediation. Journal of Hazardous Materials, 164, 73–80.
  • Huser, B. J. (2012). Variability in phosphorus binding by aluminum in alum treated lakes explained by lake morphology and aluminum dose. Water Research, 46, 4697–4704.
  • Huser, B. J., Brezonik, P., and Newman, R. (2011). Effects of alum treatment on water quality and sediment in the Minneapolis Chain of Lakes, Minnesota, USA. Lake and Reservoir Management, 27, 220–228.
  • Huser, B. J., Egemose, S., Harper, H., Hupfer, M., Jensen, H., Pilgrim, K. M., Reitzel, K., Rydin, E., and Futter, M. (2015). Longevity and effectiveness of aluminum addition to reduce sediment phosphorus release and restore lake water quality. Water Research, 97, 122–132.
  • Huser, B. J., and Pilgrim, K. M. (2014). A simple model for predicting aluminum bound phosphorus formation and internal loading reduction in lakes after aluminum addition to lake sediment. Water Research, 53, 378–385.
  • Hutchinson, G. E. (1973). Eutrophication. American Scientist, 61, 269–279.
  • Ichihara, M., and Nishio, T. (2013). Suppression of phosphorus release from sediments using water clarifier sludge as capping material. Environmental Technology, 34, 2291–2299.
  • Immers, A. K., Bakker, E. S., Van Donk, E., Ter Heerdt, G. N. J., Geurts, J. J. M., and Declerck, S. A. J. (2015). Fighting internal phosphorus loading: An evaluation of the large scale application of gradual Fe-addition to a shallow peat lake. Ecological Engineering, 83, 78–89.
  • Immers, A. K., Van der Sande, M. T., Van der Zande, R. M., Geurts, J. J. M., Van Donk, E., and Bakker, E. S. (2013). Iron addition as a shallow lake restoration measure: Impacts on charophyte growth. Hydrobiologia, 710, 241–251.
  • Immers, A. K., Vendrig, K., Ibelings, B. W., Van Donk, E., Ter Heerdt, G. N. J., Geurts, J. J. M., and Bakker, E. S. (2014). Iron addition as a measure to restore water quality: Implications for macrophyte growth. Aquatic Botany, 116, 44–52.
  • Ippolito, J. A., Barbarick, K. A., and Elliott, H. A. (2011). Drinking water treatment residuals: A review of recent uses. Journal of Environmental Quality, 40, 1–12.
  • Ippolito, J. A., Scheckel, K. G., and Barbarick, K. A. (2009). Selenium adsorption to aluminum based water treatment residuals. Journal of Colloid and Interface Science, 338, 48–55.
  • Jacobs, P. H., and Förstner, U. (1999). Concept of subaqueous capping of contaminated sediments with active barrier systems (ABS) using natural and modified zeolites. Water Research, 33, 2083–2087.
  • Jacoby, J. M., Gibbons, H. L., Stoops, K. B., and Bouchard, D. D. (1994). Response of a shallow, polymictic lake to buffered alum treatment. Lake and Reservoir Management, 10, 103–112.
  • Jaeger, D. (1994). Effects of hypolimnetic water aeration and iron-phosphate precipitation on the trophic level of Lake Krupunder. Hydrobiologia, 275, 433–444.
  • James, W. F. (2005). Alum: Redox-sensitive phosphorus ratio considerations and uncertainties in the estimation of alum dosage to control sediment phosphorus. Lake and Reservoir Management, 21, 159–164.
  • James, W. F. (2011). Variations in the aluminum:phosphorus binding ratio and alum dosage considerations for Half Moon Lake, Wisconsin. Lake and Reservoir Management, 27, 128–137.
  • James, W. F., Barko, J. W., and Taylor, W. D. (1991). Effects of alum treatment on phosphorus dynamics in a north-temperate reservoir. Hydrobiologia, 215, 231–241.
  • Jančula, D., and Maršálek, B. (2012). Seven years from the first application of polyaluminium chloride in the Czech Republic – effects on phytoplankton communities in three water bodies. Chemistry and Ecology, 28, 535–544.
  • Jansson, M. (1986). Nitrate as a catalyst for phosphorus mobilization in sediments. In Sly, P. G. (Ed.), Sediments and water interactions (pp. 387–389). New York: Springer.
  • Jensen, H. S., and Andersen, F. ∅. (1992). Importance of temperature, nitrate, and pH for phosphate release from aerobic sediments of four shallow, eutrophic lakes. Limnology and Oceanography, 37, 577–589.
  • Jensen, H. S., Kristensen, P., Jeppesen, E., and Skytthe, A. (1992). Iron:phosphorus ratio in surface sediment as an indicator of phosphate release from aerobic sediments in shallow lakes. Hydrobiologia, 235, 731–743.
  • Jensen, H. S., Reitzel, K., and Egemose, S. (2015). Evaluation of aluminum treatment efficiency on water quality and internal phosphorus cycling in six Danish lakes. Hydrobiologia, 751, 189–199.
  • Jiang, X., Jin, X. C., Yao, Y., Li, L. H., and Wu, F. C. (2008). Effects of biological activity, light, temperature and oxygen on phosphorus release processes at the sediment and water interface of Taihu Lake, China. Water Research, 42, 2251–2259.
  • Jin, X. C., Wang, S. R., Pang, Y., and Wu, F. C. (2006). Phosphorus fractions and the effect of pH on the phosphorus release of the sediments from different trophic areas in Taihu Lake, China. Environmental Pollution, 139, 288–295.
  • Jing, L. D., Wu, C. X., Liu, J. T., Wang, H. G., and Ao, H. Y. (2013). The effects of dredging on nitrogen balance in sediment-water microcosms and implications to dredging projects. Ecological Engineering, 52, 167–174.
  • Kaggwa, R. C., Mulalelo, C. I., Dennyc, P., and Okurut, T. O. (2001). The impact of alum discharges on a natural tropical wetland in Uganda. Water Research, 35, 795–807.
  • Katsev, S., Tsandev, I., L'Heureux, I., and Rancourt, D. G. (2006). Factors controlling long-term phosphorus efflux from lake sediments: Exploratory reactive-transport modeling. Chemical Geology, 234, 127–147.
  • Kennedy, R. H., and Cooke, G. D. (1982). Control of lake phosphorus with aluminum sulfate –Dose determination and application techniques. JAWRA Journal of the American Water Resources Association, 18, 389–395.
  • Kim, G., Jeong, W., Choi, S., Khim, J. (2007a). Sand capping for controlling phosphorus release from lake sediments. Environmental Technology, 28, 381–389.
  • Kim, G., and Jung, W. (2010). Role of sand capping in phosphorus release from sediment. KSCE Journal of Civil Engineering, 14, 815–821.
  • Kim, H. S., and Park, J. (2008). Effects of limestone on the dissolution of phosphate from sediments under anaerobic condition. Environmental Technology, 29, 375–380.
  • Kim, S. K., Park, Y. J., Yun, S. L., Lee, M. K. (2007b). Efficiency of gypsum as a capping material for the capturing of phosphorus release from contaminated lake sediments. Materials Science Forum, 544–545, 561–564.
  • Kleeberg, A., Herzog, C., and Hupfer, M. (2013). Redox sensitivity of iron in phosphorus binding does not impede lake restoration. Water Research, 47, 1491–1502.
  • Kleeberg, A., Köhler, A., and Hupfer, M. (2012). How effectively does a single or continuous iron supply affect the phosphorus budget of aerated lakes?. Journal of Soils and Sediments, 12, 1593–1603.
  • Knapp, S. M., and Soltero, R. A. (1983). Trout-zooplankton relationships in Medical Lake, WA following restoration by aluminum sulfate treatment. Journal of Freshwater Ecology, 2, 1–12.
  • Köhler, J., Hilt, S., Adrian, R., Nicklisch, A., Kozerski, H. P., and Walz, N. (2005). Long-term response of a shallow, moderately flushed lake to reduced external phosphorus and nitrogen loading. Freshwater Biology, 50, 1639–1650.
  • Kopáček, J., Borovec, J., Hejzlar, J., Ulrich, K. U., Norton, S. A., and Amirbahman, A. (2005). Aluminum control of phosphorus sorption by lake sediments. Environmental Science & Technology, 39, 8784–8789.
  • Lam, A. K., and Prepas, E. E. (1997). In situ evaluation of options for chemical treatment of hepatotoxic cyanobacterial blooms. Canadian Journal of Fisheries and Aquatic Sciences, 54, 1736–1742.
  • Landman, M. J., and Ling, N. (2011). Fish health changes in Lake Okaro, New Zealand: Effects of nutrient remediation, season or eutrophication? Hydrobiologia, 661, 65–79.
  • Leoni, B., Morabito, G., Rogora, M., Pollastro, D., Mosello, R., Arisci, S., and Garibaldi, L. (2007). Response of planktonic communities to calcium hydroxide addition in a hardwater eutrophic lake: Results from a mesocosm experiment. Limnology, 8, 121–130.
  • Lepistö, L., Holopainen, A. L., and Vuoristo, H. (2004). Type-specific and indicator taxa of phytoplankton as a quality criterion for assessing the ecological status of Finnish boreal lakes. Limnologica-Ecology and Management of Inland Waters, 34, 236–248.
  • Lewandowski, J., Schauser, I., and Hupfer, M. (2003). Long term effects of phosphorus precipitations with alum in hypereutrophic Lake Süsser See (Germany). Water Research, 37, 3194–3204.
  • Lin, J. W., Zhan, Y. H., and Zhu, Z. L. (2011). Evaluation of sediment capping with active barrier systems (ABS) using calcite/zeolite mixtures to simultaneously manage phosphorus and ammonium release. Science of the Total Environment, 409, 638–646.
  • Linkov, I., von Stackelberg, K. E., Burmistrov, D., and Bridges, T. S. (2001). Uncertainty and variability in risk from trophic transfer of contaminants in dredged sediments. Science of the Total Environment, 274, 255–269.
  • Liu, B., Liu, X. G., Yang, J., Garman, D. E. J., Zhang, K., and Zhang, H. G. (2012). Research and application of in-situ control technology for sediment rehabilitation in eutrophic water bodies. Water Science and Technology, 65, 1190–1199.
  • Liu, G. R., Ye, C. S., Qian, Q., He, J. H., and Jiang, H. (2009). Effects of in-situ sediment treatment of phosphorus release in Wuhan East Lake, China. Fresenius Environmental Bulletin, 18, 1888–1893.
  • Liu, Y. B., Guo, Y. X., Song, C. L., Xiao, W. J., Huang, D. Z., Cao, X. Y., and Zhou, Y. Y. (2009). The effect of organic matter accumulation on phosphorus release in sediment of Chinese shallow lakes. Fundamental and Applied Limnology / Archiv für Hydrobiologie, 175, 143–150.
  • Łopata, M., and Gawrońska, H. (2008). Phosphorus immobilization in Lake Gleboczek following treatment with polyaluminum chloride. Oceanological and Hydrobiological Studies, 37, 99–105.
  • Lu, S. Y., Jin, X. C., Liang, L. L., Xin, W. G., Zheng, M. Z., Xu, D., and Wu, F. C. (2013). Influence of inactivation agents on phosphorus release from sediment. Environmental Earth Sciences, 68, 1143–1151.
  • Lürling, M., and Faassen, E. J. (2012). Controlling toxic cyanobacteria: effects of dredging and phosphorus-binding clay on cyanobacteria and microcystins. Water Research, 46, 1447–1459.
  • Lürling, M., and Tolman, Y. (2010). Effects of lanthanum and lanthanum-modified clay on growth, survival and reproduction of Daphnia magna. Water Research, 44, 309–319.
  • Lürling, M., and van Oosterhout, F. (2013a). Case study on the efficacy of a lanthanum-enriched clay (Phoslock) in controlling eutrophication in Lake Het Groene Eiland (the Netherlands). Hydrobiologia, 710, 253–263.
  • Lürling, M., and van Oosterhout, F. (2013b). Controlling eutrophication by combined bloom precipitation and sediment phosphorus inactivation. Water Research, 47, 6527–6537.
  • Lürling, M., Waajen, G., and van Oosterhout, F. (2014). Humic substances interfere with phosphate removal by lanthanum modified clay in controlling eutrophication. Water Research, 54, 78–88.
  • Mackay, E. B., Maberly, S. C., Pan, G., Reitzel, K., Bruere, A., Corker, N., Douglas, G., Egemose, S., Hamilton, D., Hatton-Ellis, T., Huser, B., Li, W., Meis, S., Moss, B., Lürling, M., Phillips, G., Yasseri, S., and Spears, B. M. (2014). Geoengineering in lakes: welcome attraction or fatal distraction?. Inland Waters, 4, 349–356.
  • Makris, K. C., Harris, W. G., O'Connor, G. A., Obreza, T. A., and Elliott, H. A. (2005). Physicochemical properties related to long-term phosphorus retention by drinking-water treatment residuals. Environmental Science & Technology, 39, 4280–4289.
  • Makris, K. C., Sarkar, D., and Datta, R. (2006a). Evaluating a drinking-water waste by-product as a novel sorbent for arsenic. Chemosphere, 64, 730–741.
  • Makris, K. C., Sarkar, D., and Datta, R. (2006b). Aluminum-based drinking-water treatment residuals: A novel sorbent for perchlorate removal. Environmental Pollution, 140, 9–12.
  • Márquez-Pacheco, H., Hansen, A. M., and Falcón-Rojas, A. (2013). Phosphorous control in a eutrophied reservoir. Environmental Science and Pollution Research, 20, 8446–8456.
  • Matthews, D. A., Babcock, D. B., Nolan, J. G., Prestigiacomo, A. R., Effler, S. W., Driscoll, C. T., Todorova, S. G., and Kuhr, K. M. (2013). Whole-lake nitrate addition for control of methylmercury in mercury-contaminated Onondaga Lake, NY. Environmental Research, 125, 52–60.
  • Mehner, T., Diekmann, M., Gonsiorczyk, T., Kasprzak, P., Koschel, R., Krienitz, L., Rumpf, M., Schulz, M., and Wauer, G. (2008). Rapid recovery from eutrophication of a stratified lake by disruption of internal nutrient load. Ecosystems, 11, 1142–1156.
  • Meis, S., Spears, B. M., Maberly, S. C., O'Malley, M. B., and Perkins, R. G. (2012). Sediment amendment with Phoslock in Clatto Reservoir (Dundee, UK): Investigating changes in sediment elemental composition and phosphorus fractionation. Journal of Environmental Management, 93, 185–193.
  • Meis, S., Spears, B. M., Maberly, S. C., and Perkins, R. G. (2013). Assessing the mode of action of Phoslock in the control of phosphorus release from the bed sediments in a shallow lake (Loch Flemington, UK). Water Research, 47, 4460–4473.
  • Mesner, N., and Narf, R. (1987). Alum injection into sediments for phosphorus inactivation and macrophyte control. Lake and Reservoir Management, 3, 256–265.
  • Mires, J. M., Soltero, R. A., and Keizur, G. R. (1981). Changes in the zooplankton community of Medical Lake, WA, subsequent to its restoration by a whole-lake alum treatment and the establishment of a trout fishery. Journal of Freshwater Ecology, 1, 167–178.
  • Miskimmin, B. M., Donahue, W. F., and Watson, D. (1995). Invertebrate community response to experimental lime (Ca(OH)2) treatment of an eutrophic pond. Aquatic Sciences, 57, 20–30.
  • Moore, B. C., and Christensen, D. (2009). Newman Lake restoration: A case study. Part I. Chemical and biological responses to phosphorus control. Lake and Reservoir Management, 25, 337–350.
  • Moore, B. C., Cross, B. K., Beutel, M., Dent, S., Preece, E., and Swanson, M. (2012). Newman lake restoration: a case study Part III. Hypolimnetic oxygenation. Lake and Reservoir Management, 28, 311–327.
  • Moos, M. T., Taffs, K. H., Longstaff, B. J., and Ginn, B. K. (2014). Establishing ecological reference conditions and tracking post-application effectiveness of lanthanum-saturated bentonite clay (Phoslock) for reducing phosphorus in aquatic systems: An applied paleolimnological approach. Journal of Environmental Management, 141, 77–85.
  • Mortula, M., Bard, S. M., Walsh, M. E., and Gagnon, G. A. (2009). Alum toxicity and ecological risk assessment of dried alum residual into surface water disposal. Canadian Journal of Civil Engineering, 36, 127–136.
  • Muisa, N., Hoko, Z., and Chifamb, P. (2011). Impacts of alum residues from Morton Jaffray Water Works on water quality and fish, Harare, Zimbabwe. Physics and Chemistry of the Earth, Parts A/B/C, 36, 853–864.
  • Murphy, T. P., Hall, K. G., and Northcote, T. G. (1988). Lime treatment of a hardwater lake to reduce eutrophication. Lake and Reservoir Management, 4, 51–62.
  • Na, Y. M., and Park, S. S. (2004). Retardation of phosphate release from freshwater benthic sediments by application of ocher pellets with calcium nitrate. Journal of Environmental Science and Health Part A, 39, 1617–1629.
  • Nagar, R., Sarkar, D., Makris, K. C., and Datta, R. (2010). Effect of solution chemistry on arsenic sorption by Fe- and Al-based drinking-water treatment residuals. Chemosphere, 78, 1028–1035.
  • Nagar, R., Sarkar, D., Makris, K. C., and Datta, R. (2013). Inorganic arsenic sorption by drinking-water treatment residual-amended sandy soil: Effect of soil solution chemistry. International Journal of Environmental Science and Technology, 10, 1–10.
  • Narf, R. P. (1990). Interactions of Chironomidae and Chaoboridae (Diptera) with aluminum sulfate treated lake sediments. Lake and Reservoir Management, 6, 33–42.
  • Neal, C. (2001). The potential for phosphorus pollution remediation by calcite precipitation in UK freshwaters. Hydrology and Earth System Sciences, 5, 119–131.
  • Nicholls, K. H. (1999). Effects of temperature and other factors on summer phosphorus in the inner bay of Quinte, Lake Ontario: Implications for climate warming. Journal of Great Lakes Research, 25, 250–262.
  • Nogaro, G., Burgin, A. J., Schoepfer, V. A., Konkler, M. J., Bowman, K. L., and Hammerschmidt, C. R. (2013). Aluminum sulfate (alum) application interactions with coupled metal and nutrient cycling in a hypereutrophic lake ecosystem. Environmental Pollution, 176, 267–274.
  • Oliver, I. W., Grant, C. D., and Murray, R. S. (2011). Assessing effects of aerobic and anaerobic conditions on phosphorus sorption and retention capacity of water treatment residuals. Journal of Environmental Management, 92, 960–966.
  • Özkundakci, D., Duggan, I. C., and Hamilton, D. P. (2011b). Does sediment capping have post-application effects on zooplankton and phytoplankton?. Hydrobiologia, 661, 55–64.
  • Özkundakci, D., Hamilton, D. P., and Gibbs, M. M. (2011a). Hypolimnetic phosphorus and nitrogen dynamics in a small, eutrophic lake with a seasonally anoxic hypolimnion. Hydrobiologia, 661, 5–20.
  • Özkundakci, D., Hamilton, D. P., and Scholes, P. (2010). Effect of intensive catchment and in-lake restoration procedures on phosphorus concentrations in a eutrophic lake. Ecological Engineering, 36, 396–405.
  • Pace, M. L., and Prairie, Y. T. (2005). Respiration in lakes. In: del Giorgio, P. A., P. J.leB., Williams (Eds.), Respiration in Aquatic Ecosystems (pp. 103–121). New York: Oxford University Press.
  • Pan, G., Dai, L. C., Li, L., He, L. C., Li, H., Bi, L., and Gulati, R. D. (2012). Reducing the recruitment of sedimented algae and nutrient release into the overlying water using modified soil/sand flocculation-capping in eutrophic lakes. Environmental Science & Technology, 46, 5077–5084.
  • Pan, G., Yang, B., Wang, D., Chen, H., Tian, B. H., Zhang, M. L., Yuan, X. Z., and Chen, J. (2011). In-lake algal bloom removal and submerged vegetation restoration using modified local soils. Ecological Engineering, 37, 302–308.
  • Pan, G., Zou, H., Chen, H., and Yuan, X. Z. (2006). Removal of harmful cyanobacterial blooms in Taihu Lake using local soils III. Factors affecting the removal efficiency and an in situ field experiment using chitosan-modified local soils. Environmental Pollution, 141, 206–212.
  • Park, Y. J., Ko, J. J., Kim, Y. I., Yun, S. L., Kim, S. J., and Lee, B. C. (2007). Application of gypsum granule as a capping material to reduce phosphorus release from sediment of lake paldang. Materials Science Forum, 544–545, 521–524.
  • Parkyn, S. M., Hickey, C. W., and Clearwater, S. J. (2011). Measuring sub-lethal effects on freshwater crayfish (Paranephrops planifrons) behaviour and physiology: laboratory and in situ exposure to modified zeolite. Hydrobiologia, 661, 37–53.
  • Paul, W. J., Hamilton, D. P., and Gibbs, M. M. (2008). Low-dose alum application trialled as a management tool for internal nutrient loads in Lake Okaro, New Zealand. New Zealand Journal of Marine and Freshwater Research, 42, 207–217.
  • Payne, F. E., Laurin, C. R., Thornton, K. W., and Sual, G. E. (1991). A strategy for evaluating in-lake treatment effectiveness and longevity. Terrene Institute, Washington, D.C.
  • Perakis, S. S., Welch, E. B., and Jacoby, J. M. (1996). Sediment-to-water blue-green algal recruitment in response to alum and environmental factors. Hydrobiologia, 318, 165–177.
  • Perelo, L. W. (2010). Review: In situ and bioremediation of organic pollutants in aquatic sediments. Journal of Hazardous Materials, 177, 81–89.
  • Peterson, S. A., Sanville, W. D., Stay, F. S., and Powers, C. F. (1976). Laboratory Evaluation of Nutrient Inactivation Compounds for Lake Restoration. Journal (Water Pollution Control Federation), 48, 817–831.
  • Phillips, G., Kelly, A., Pitt, J. A., Sanderson, R., and Taylor, E. (2005). The recovery of a very shallow eutrophic lake, 20 years after the control of effluent derived phosphorus. Freshwater Biology, 50, 1628–1638.
  • Pilgrim, K. M., Huser, B. J., and Brezonik, P. L. (2007). A method for comparative evaluation of whole-lake and inflow alum treatment. Water Research, 41, 1215–1224.
  • Playle, R. C. (1987). Chemical effects of spring and summer alum additions to a small, Northwestern Ontario Lake. Water Air and Soil Pollution, 34, 207–225.
  • Prepas, E. E., Babin, J., Murphy, T. P., Chambers, P. A., Sandland, G. J., Ghadouani, A., and Serediak, M. (2001a). Long-term effects of successive Ca(OH)2 and CaCO3 treatments on the water quality of two eutrophic hardwater lakes. Freshwater Biology, 46, 1089–1103.
  • Prepas, E. E., Murphy, T. P., Crosby, J. M., Walty, D. T., Lim, J. T., Babin, J., and Chambers, P. A. (1990). Reduction of phosphorus and chlorophyll-a concentrations following CaCO3 and Ca(OH)2 additions to hypereutrophic Figure 8 Lake, Alberta. Environmental Science & Technology, 24, 1252–1258.
  • Prepas, E. E., Pinel-Alloul, B., Chambers, P. A., Murphy, T. P., Reedyk, S., Sandland, G., and Serediak, M. (2001b). Lime treatment and its effects on the chemistry and biota of hardwater eutrophic lakes. Freshwater Biology, 46, 1049–1060.
  • Proft, G., and Stutter, E. (1993). Calcite precipitation in hard water lakes in calculation and experiment. Internationale Revue der gesamten Hydrobiologie und Hydrographie, 78, 177–199.
  • Putra, R. S., and Tanaka, S. (2011). Aluminum drinking water treatment residuals (Al-WTRs) as an entrapping zone for lead in soil by electrokinetic remediation. Separation and Purification Technology, 79, 208–215.
  • Qin, B. Q. (2009). Lake eutrophication: Control countermeasures and recycling exploitation. Ecological Engineering, 35, 1569–1573.
  • Qiu, S., and McComb, A. J. (1995). Planktonic and microbial contributions to phosphorus release from fresh and air-dried sediments. Marine and Freshwater Research, 46, 1039–1045.
  • Quaak, M., van der Does, J., Boers, P., and van der Vlugt, J. (1993). A new technique to reduce internal phosphorus loading by in-lake phosphate fixation in shallow lakes. Hydrobiologia, 253, 337–344.
  • Randall, S., Harper, D., and Brierley, B. (1999). Ecological and ecophysiological impacts of ferric dosing in reservoirs. Hydrobiologia, 395, 355–364.
  • Razali, M., Zhao, Y. Q., and Bruen, M. (2007). Effectiveness of a drinking-water treatment sludge in removing different phosphorus species from aqueous solution. Separation and Purification Technology, 55, 300–306.
  • Reedyk, S., Prepas, E. E., and Chambers, P. A. (2001). Effects of single Ca(OH)2 doses on phosphorus concentration and macrophyte biomass of two boreal eutrophic lakes over 2 years. Freshwater Biology, 46, 1075–1087.
  • Reitzel, K., Ahlgren, J., Gogoll, A., and Rydin, E. (2006). Effects of aluminum treatment on phosphorus, carbon, and nitrogen distribution in lake sediment: A 31P NMR study. Water Research, 40, 647–654.
  • Reitzel, K., Andersen, F. ∅., Egemose, S., and Jensen, H. S. (2013a). Phosphate adsorption by lanthanum modified bentonite clay in fresh and brackish water. Water Research, 47, 2787–2796.
  • Reitzel, K., Hansen, J., Andersen, F. ∅., Hansen, K. S., and Jensen, H. S. (2005). Lake restoration by dosing aluminum relative to mobile phosphorus in the sediment. Environmental Science & Technology, 39, 4134–4140.
  • Reitzel, K., Hansen, J., Jensen, H. S., Andersen, F. ∅., and Hansen, K. S. (2003). Testing aluminum addition as a tool for lake restoration in shallow, eutrophic Lake Sønderby, Denmark. Hydrobiologia, 506, 781–787.
  • Reitzel, K., Jensen, H. S., and Egemose, S. (2013b). pH dependent dissolution of sediment aluminum in six Danish lakes treated with aluminum. Water Research, 47, 1409–1420.
  • Reitzel, K., Lotter, S., Dubke, M., Egemose, S., Jensen, H. S., and Andersen, F. ∅. (2013c). Effects of Phoslock treatment and chironomids on the exchange of nutrients between sediment and water. Hydrobiologia, 703, 189–202.
  • Ross, G., Haghseresht, F., and Cloete, T. E. (2008). The effect of pH and anoxia on the performance of Phoslock, a phosphorus binding clay. Harmful Algae, 7, 545–550.
  • Rothe, M., Frederichs, T., Eder, M., Kleeberg, A., and Hupfer, M. (2014). Evidence for vivianite formation and its contribution to long-term phosphorus retention in a recent lake sediment: A novel analytical approach. Biogeosciences, 11, 5169–5180.
  • Rydin, E. (2000). Potentially mobile phosphorus in Lake Erken sediment. Water Research, 34, 2037–2042.
  • Rydin, E., Huser, B., and Welch, E. B. (2000). Amount of phosphorus inactivated by alum treatments in Washington lakes. Limnology and Oceanography, 45, 226–230.
  • Rydin, E., and Welch, E. B. (1998). Aluminum dose required to inactivate phosphate in lake sediments. Water Research, 32, 2969–2976.
  • Rydin, E., and Welch, E. B. (1999). Dosing alum to Wisconsin lake sediments based on in vitro formation of aluminum bound phosphate. Lake and Reservoir Management, 15, 324–331.
  • Rzepecki, M. (1997). Bottom sediments in a humic lake with artificially increased calcium content: Sink or source for phosphorus? In Evans, R. D., Wísniewski, J., and Wísniewski, J. R. (Eds.), The interactions between sediments and water (pp. 457–464). Dordrecht, the Netherlands: Springer.
  • Salonen, V. P., and Varjo, E. (2000). Gypsum treatment as a restoration method for sediments of eutrophied lakes - experiments from southern Finland. Environmental Geology, 39, 353–359.
  • Salonen, V. P., Varjo, E., and Rantala, P. (2001). Gypsum treatment in managing the internal phosphorus load from sapropelic sediments; experiments on Lake Laikkalammi, Finland. Boreal Environment Research, 6, 119–129.
  • Sanville, W. D., Powers, C. F., Schuytema, G. S., Stay, F. S., and Lauer, W. L. (1982). Phosphorus inactivation by zirconium in a eutrophic pond. Water Pollution Control Federation, 54, 434–443.
  • Schindler, D. W., Hecky, R. E., Findlay, D. L., Stainton, M. P., Parker, B. R., Paterson, M. J., Beaty, K. G., Lyng, M., and Kasian, S. E. M. (2008). Eutrophication of lakes cannot be controlled by reducing nitrogen input: Results of a 37-year whole-ecosystem experiment. Proceedings of the National Academy of Sciences of the United States of Ameirca, 105, 11254–11258.
  • Schumaker, R. J., Funk, W. H., and Moore, B. C. (1993). Zooplankton responses to aluminum sulfate treatment of Newman Lake, Washington. Journal of Freshwater Ecology, 8, 375–387.
  • Smeltzer, E., Kirn, R. A., and Fiske, S. (1999). Long-term water quality and biological effects of alum treatment of Lake Morey, Vermont. Lake and Reservoir Management, 15, 173–184.
  • Smith, V. H. (2003). Eutrophication of freshwater and coastal marine ecosystems — a global problem. Environmental Science and Pollution Research, 10, 126–139.
  • Smolders, A. J. P., Lamers, L. P. M., Moonen, M., Zwaga, K., and Roelofs, J. G. M. (2001). Controlling phosphate release from phosphate-enriched sediments by adding various iron compounds. Biogeochemistry, 54, 219–228.
  • Smolders, A. J. P., Nijboer, R. C., and Roelofs, J. G. M. (1995). Prevention of sulfide accumulation and phosphate mobilization by the addition of iron(II) chloride to a reduced sediment: an enclosure experiment. Freshwater Biology, 34, 559–567.
  • Søndergaard, M., Jensen, J. P., and Jeppesen, E. (2003). Role of sediment and internal loading of phosphorus in shallow lakes. Hydrobiologia, 506, 135–145.
  • Søndergaard, M., Jeppesen, E., and Jensen, J. P. (2000). Hypolimnetic nitrate treatment to reduce internal phosphorus loading in a stratified lake. Lake and Reservoir Management, 16, 195–204.
  • Søndergaard, M., Kristensen, P., and Jeppesen, E. (1992). Phosphorus release from resuspended sediment in the shallow and wind-exposed Lake Arresø, Denmark. Hydrobiologia, 228, 91–99.
  • Song, N., Yan, Z. S., Cai, H. Y., and Jiang, H. L. (2013). Effect of temperature on submerged macrophyte litter decomposition within sediments from a large shallow and subtropical freshwater lake. Hydrobiologia, 714, 131–144.
  • Sotero-Santos, R. B., Rocha, O., and Povinelli, J. (2005). Evaluation of water treatment sludges toxicity using the Daphnia bioassay. Water Research, 39, 3909–3917.
  • Spears, B. M., Carvalho, L., Perkins, R., and Paterson, D. M. (2008). Effects of light on sediment nutrient flux and water column nutrient stoichiometry in a shallow lake. Water Research, 42, 977–986.
  • Spears, B. M., Lürling, M., Yasseri, S., Castro-Castellom, A. T., Gibbs, M., Meis, S., McDonald, C., Mclntosh, J., Sleep, D., and van Oosterhout, F. (2013a). Lake responses following lanthanum-modified bentonite clay (Phoslock) application: An analysis of water column lanthanum data from 16 case study lakes. Water Research, 47, 5930–5942.
  • Spears, B. M., Maberly, S. C., Pan, G., Mackay, E., Bruere, A., Corker, N., Douglas, G., Egemose, S., Hamilton, D., Hatton-Ellis, T., Huser, B., Li, W., Meis, S., Moss, B., Lürling, M., Phillips, G., Yasseri, S., and Reitzel, K. (2014). Geo-engineering in lakes: A crisis of confidence? Environmental Science & Technology, 48, 9977–9979.
  • Spears, B. M., Meis, S., Anderson, A., and Kellou, M. (2013b). Comparison of phosphorus (P) removal properties of materials proposed for the control of sediment p release in UK lakes. Science of the Total Environment, 442, 103–110.
  • Spencer, D. F., Yeung, H. Y., and Greene, R. W. (1983). Alterations in the zooplankton community of a fly-ash treated lake. Hydrobiologia, 107, 123–130.
  • Steinman, A. D., and Ogdahl, M. (2008). Ecological effects after an alum treatment in Spring Lake, Michigan. Journal of Environmental Quality, 37, 22–29.
  • Steinman, A. D., and Ogdahl, M. E. (2012). Macroinvertebrate response and internal phosphorus loading in a Michigan lake after alum treatment. Journal of Environmental Quality, 41, 1540–1548.
  • Stephen, D., Moss, B., and Phillips, G. (1997). Do rooted macrophytes increase sediment phosphorus release? Hydrobiologia, 342, 27–34.
  • Sun, S. Q., Qiu, Y., Jiang, C. B., Jiang, W. X., Zhou, Q., Nie, X. B., and Tan, W. C. (2012). Study on mechanisms of in-situ moderately labile organic phosphorus control by zeolite in shallow lake sediments. Applied Mechanics and Materials, 209–211, 1142–1146.
  • Sutela, T., Aroviita, J., Keto, A. (2013). Assessing ecological status of regulated lakes with littoral macrophyte, macroinvertebrate and fish assemblages. Ecological Indicators, 24, 185–192.
  • Theis, T. L., and McCabe, P. J. (1978). Retardation of sediment phosphorus release by fly-ash application. Journal Water Pollution Control Federation, 50, 2666–2676.
  • Tirén, T., and Pettersson, K. (1985). The influence of nitrate on the phosphorus flux to and from oxygen depleted lake-sediments. Hydrobiologia, 120, 207–223.
  • Toffolon, M., Ragazzi, M., Righetti, M., Teodoru, C. R., Tubino, M., Defrancesco, C., and Pozzi, S. (2013). Effects of artificial hypolimnetic oxygenation in a shallow lake. Part1: Phenomenological description and management. Journal of Environmental Management, 114, 520–529.
  • Tuominen, L., Hartikainen, H., Kairesalo, T., and Tallberg, P. (1998). Increased bioavailability of sediment phosphorus due to silicate enrichment. Water Research, 32, 2001–2008.
  • Van Hullebusch, E., Auvray, F., Deluchat, V., Chazal, P. M., and Baudu, M. (2003). Phosphorus fractionation and short-term mobility in the surface sediment of a polymictic shallow lake treated with a low dose of alum (Courtille Lake, France). Water Air and Soil Pollution, 146 (1–4), 75–91.
  • Van Hullebusch, E., Deluchat, V., Chazal, P. M., and Baudu, M. (2002). Environmental impact of two successive chemical treatments in a small shallow eutrophied lake: Part I. Case of aluminium sulfate. Environmental Pollution, 120, 617–626.
  • Van Oosterhout, F., and Lürling, M. (2011). Effects of the novel ‘Flock & Lock’ lake restoration technique on Daphnia in Lake Rauwbraken (the Netherlands). Journal of Plankton Research, 33, 255–263.
  • Van Oosterhout, F., and Lürling, M. (2013). The effect of phosphorus binding clay (Phoslock) in mitigating cyanobacterial nuisance: A laboratory study on the effects on water quality variables and plankton. Hydrobiologia, 710, 265–277.
  • Varjo, E., Liikanen, A., Salonen, V. P., and Martikainen, P. J. (2003). A new gypsum-based technique to reduce methane and phophorus release from sediments of eutrophied lakes: (Gypsum treatment to reduce internal loading). Water Research, 37, 1–10.
  • Vopel, K., Gibbs, M., Hickey, C. W., and Quinn, J. (2008). Modification of sediment-water solute exchange by sediment-capping materials: effects on O2 and pH. Marine and Freshwater Research, 59, 1101–1110.
  • Wahlström, G., and Danilov, R. A. (2003). Phytoplankton successions under ice cover in four lakes located in North-Eastern Sweden: effects of liming. Folia Microbiologica, 48, 379–384.
  • Wang, C. H., Bai, L. L., and Pei, Y. S. (2013a). Assessing the stability of phosphorus in lake sediments amended with water treatment residuals. Journal of Environmental Management, 122, 31–36.
  • Wang, C. H., Fei, C. B., and Pei, Y. S. (2012a). Stability of P saturated water treatment residuals under different levels of dissolved oxygen. Clean-Soil Air Water, 40, 844–849.
  • Wang, C. H., Gao, S. J., Pei, Y. S., and Zhao, Y. Q. (2013b). Use of drinking water treatment residuals to control the internal phosphorus loading from lake sediments: Laboratory scale investigation. Chemical Engineering Journal, 225, 93–99.
  • Wang, C. H., Liang, J. C., Pei, Y. S., and Wendling, L. A. (2013c). A method for determining the treatment dosage of drinking water treatment residuals for effective phosphorus immobilization in sediments. Ecological Engineering, 60, 421–427.
  • Wang, C. H., Liu, J. F., and Pei, Y. S. (2013d). Effect of hydrogen sulfide on phosphorus lability in lake sediments amended with drinking water treatment residuals Chemosphere. 91 (9), 1344–1348.
  • Wang, C. H., Liu, J. F., Wang, Z. X., and Pei, Y. S. (2014a). Nitrification in lake sediment with addition of drinking water treatment residuals. Water Research, 56 (1), 234–245.
  • Wang, C. H., and Pei, Y. S. (2013a). A comparison of the phosphorus immobilization capabilities of water treatment residuals before and after settling from lake water. Separation and Purification Technology, 30, 83–88.
  • Wang, C. H., and Pei, Y. S. (2013b). Effects of light, microbial activity, and sediment resuspension on the phosphorus immobilization capability of drinking water treatment residuals in lake sediment. Environmental Science and Pollution Research, 20, 8900–8908.
  • Wang, C. H., Qi, Y., and Pei, Y. S. (2012b). Laboratory investigation of phosphorus immobilization in lake sediments using water treatment residuals. Chemical Engineering Journal, 209, 379–385.
  • Wang, C. H., Wang, Z. Y., Lin, L., Tian, B. H., and Pei, Y. S. (2012c). Effect of low molecular weight organic acids on phosphorus adsorption by ferric-alum water treatment residuals. Journal of Hazardous Materials, 203, 145–150.
  • Wang, C. H., Yuan, N. N., and Pei, Y. S. (2014b). An anaerobic incubation study of metal lability in drinking watertreatment residue with implications for practical reuse. Journal of Hazardous Materials, 274, 15, 342–348.
  • Wang, C. H., Yuan, N. N., and Pei, Y. S. (2014c). Effect of pH on metal lability in drinking water treatment residuals. Journal of Environmental Quality, 43 (1), 389–397.
  • Wang, C. H., Yuan, N. N., Pei, Y. S., and Jiang, H.-L. (2015). Aging of aluminum/iron-based drinking water treatment residuals in lake water and their association with phosphorus immobilization capability. Journal of Environmental Management, 159, 178–185.
  • Wang, Q. R., and Li, Y. C. (2010). Phosphorus adsorption and desorption behavior on sediments of different origins. Journal of Soils and Sediments, 10, 1159–1173.
  • Wang, S. R., Jin, X. C., Zhao, H. C., and Wu, F. C. (2009). Phosphorus release characteristics of different trophic lake sediments under simulative disturbing conditions. Journal of Hazardous Materials, 161, 1551–1559.
  • Wang, S. R., Jin, X. C., Zhao, H. C., Zhou, X. N., and Wu, F. C. (2008). Effects of organic matter on phosphorus release kinetics in different trophic lake sediments and application of transition state theory. Journal of Environmental Management, 88, 845–852.
  • Wang, X. Y., and Feng, J. (2007). Assessment of the effectiveness of environmental dredging in South Lake, China. Environmental Management, 40, 314–322.
  • Wang, Z. Y., Wang, C. H., Wang, Z. X., and Pei, Y. S. (2013e). Enhancement of anaerobic ammonium oxidation in lake sediment by applying drinking water treatment residuals. Bioresource Technology, 142, 745–749.
  • Wauer, G., Gonsiorczyk, T., Casper, P., and Koschel, R. (2005b). P-immobilisation and phosphatase activities in lake sediment following treatment with nitrate and iron. Limnologica, 35, 102–108.
  • Wauer, G., Gonsiorczyk, T., Hupfer, M., and Koschel, R. (2009). Phosphorus balance of Lake Tiefwarensee during and after restoration by hypolimnetic treatment with aluminum and calcium salts. Lake and Reservoir Management, 25, 377–388.
  • Wauer, G., Gonsiorczyk, T., Kretschmer, K., Casper, P., and Koschel, R. (2005a). Sediment treatment with a nitrate-storing compound to reduce phosphorus release. Water Research, 39, 494–500.
  • Wauer, G., and Teien, H. C. (2010). Risk of acute toxicity for fish during aluminium application to hardwater lakes. Science of the Total Environment, 408, 4020–4025.
  • Welch, E. B., and Cooke, G. D. (1999). Effectiveness and longevity of phosphorus inactivation with alum. Lake and Reservoir Management, 15, 5–27.
  • Welch, E. B., and Schrieve, G. D. (1994). Alum treatment effectiveness and longevity in shallow lakes. Hydrobiologia, 275, 423–431.
  • Willenbring, P. R., Miller, M. S., and Weidenbacher, W. D. (1984). Reducing sediment phosphorus release rates in Long Lake through the use of calcium nitrate. Lake and Reservoir Management, 1, 118–121.
  • Wísniewski, R. (1999). Phosphate inactivation with iron chloride during sediment resuspension. Lakes & Reservoirs: Research and Management, 4, 65–73.
  • Wold, L. A., Moore, B. C., and Dasgupta, N. (2005). Life-history responses of Daphnia pulex with exposure to aluminum sulfate. Lake and Reservoir Management, 21, 383–390.
  • Xie, L., Xie, P., Li, S., Tang, H., and Liu, H. (2003a). The low TN:TP ratio, a cause or a result of Microcystis blooms?. Water Research, 37, 2073–2080.
  • Xie, L. Q., Xie, P., and Tang, H. J. (2003b). Enhancement of dissolved phosphorus release from sediment to lake water by Microcystis blooms — an enclosure experiment in a hyper-eutrophic, subtropical Chinese lake. Environmental Pollution, 122, 391–399.
  • Xiong, W. H., and Peng, J. (2011). Laboratory-scale investigation of ferrihydrite-modified diatomite as a phosphorus co-precipitant. Water, Air & Soil Pollution, 215, 645–654.
  • Xiong, W. H., and Peng, J. (2014). Combined application of ferrihydrite-modified diatomite and gypsum to phosphorus control in a laboratory-scale artificial aquarium. Water, Air & Soil Pollution, 225, 1855.
  • Xu, D., Ding, S. M., Sun, Q., Zhong, J. C., Wu, W., and Jia, F. (2012). Evaluation of in situ capping with clean soils to control phosphate release from sediments. Science of the Total Environment, 438, 334–341.
  • Xu, H., Paerl, H. W., Qin, B., Zhu, G., and Gao, G. (2010). Nitrogen and phosphorus inputs control phytoplankton growth in eutrophic Lake Taihu, China. Limnology and Oceanography, 55, 420–432.
  • Yamada, H., Kayama, M., Saito, K., and Hara, M. (1987). Suppression of phosphate liberation fromsediment by using iron slag. Water Research, 21, 325–333.
  • Yamada, T. M., Sueitt, A. P. E., Beraldo, D. A. S., Botta, C. M. R., Fadini, P. S., Nascimento, M. R. L., Faria, B. M., and Mozeto, A. A. (2012). Calcium nitrate addition to control the internal load of phosphorus from sediments of a tropical eutrophic reservoir: Microcosm experiments. Water Research, 46, 6463–6475.
  • Yang, M., Lin, J., Zhan, Y., and Zhang, H. (2014). Adsorption of phosphate from water on lake sediments amended with zirconium-modified zeolites in batch mode. Ecological Engineering, 71, 223–233.
  • Yang, M., Lin, J., Zhan, Y., Zhu, Z., and Zhang, H. (2015). Immobilization of phosphorus from water and sediment using zirconium-modified zeolites. Environmental Science and Pollution Research, 22, 3606–3619.
  • Yang, Y., Zhao, Y. Q., Babatunde, A. O., Wang, L., Ren, Y. X., and Han, Y. (2006). Characteristics and mechanisms of phosphate adsorption on dewatered alum sludge. Separation and Purification Technology, 51, 193–200.
  • Yang, Y., Zhao, Y. Q., and Kearney, P. (2008). Influence of ageing on the structure and phosphate adsorption capacity of dewatered alum sludge. Chemical Engineering Journal, 145, 276–284.
  • Ye, H. P., Chen, F. Z., Sheng, Y. Q., Sheng, G. Y., and Fu, J. M. (2006). Suppression of phosphate liberation from eutrophic lake sediment by using fly ash and ordinary Portland cement. Journal of Environmental Science and Health Part A, 41, 1655–1666.
  • Yee, K. A., Prepas, E. E., Chambers, P. A., Culp, J. M., and Scrimgeour, G. (2000). Impact of Ca(OH)2 treatment on macroinvertebrate communities in eutrophic hardwater lakes in the Boreal Plain region of Alberta: in situ and laboratory experiments. Canadian Journal of Fisheries and Aquatic Sciences, 57, 125–136.
  • Yin, H. B., Kong, M., and Fan, C. X. (2013). Batch investigations on P immobilization from wastewaters and sediment using natural calcium rich sepiolite as a reactive material. Water Research, 47, 4247–4258.
  • Yuan, X. Z., Pan, G., Chen, H., and Tian, B. H. (2009). Phosphorus fixation in lake sediments using LaCl3-modified clays. Ecological Engineering, 35, 1599–1602.
  • Yun, S. L., Kim, S. J., Park, Y. J., Kang, S. W., Kwak, P. J., Ko, J. J., and Ahn, J. H. (2007). Evaluation of capping materials for the stabilization of contaminated sediments. Materials Science Forum, 544–545, 565–568.
  • Zamparas, M., Deligiannakis, Y., and Zacharias, I. (2013). Phosphate adsorption from natural waters and evaluation of sediment capping using modified clays. Desalination and Water Treatment, 51, 2895–2902.
  • Zamparas, M., and Zacharias, I. (2014). Restoration of eutrophic freshwater by managing internal nutrient loads. A review. Science of the Total Environment, 496, 551–562.
  • Zhang, R. Y., Wu, F. C., Liu, C. Q., Fu, P. Q., Li, W., Wang, L. Y., Liao, H. Q., and Guo, J. Y. (2008). Characteristics of organic phosphorus fractions in different trophic sediments of lakes from the middle and lower reaches of Yangtze River region and Southwestern Plateau. China. Environmental Pollution, 152, 366–372.
  • Zhang, Y., Ghadouani, A., Prepas, E. E., Pinel-Alloul, B., Reedyk, S., Chambers, P. A., Robarts, R. D., Méthot, G., Raik, A., and Holst, M. (2001). Response of plankton communities to whole-lake Ca(OH)2 and CaCO3 additions in eutrophic hardwater lakes. Freshwater Biology, 46, 1105–1119.
  • Zhang, Y., He, F., Xia, S. B., Kong, L. W., Xu, D., and Wu, Z. B. (2014). Adsorption of sediment phosphorus by porous ceramic filter mediacoated with nano-titanium dioxide film. Ecological Engineering, 64, 186–192.
  • Zhang, Y., and Prepas, E. E. (1996). Short-term effects of Ca(OH)2 additions on phytoplankton biomass: A comparison of laboratory and in situ experiments. Water Research, 30, 1285–1294.
  • Zhao, Y., Yang, Z. F., Xia, X. H., and Wang, F. (2012). A shallow lake remediation regime with Phragmites australis: Incorporating nutrient removal and water evapotranspiration. Water Research, 46, 5635–5644.
  • Zhou, Y. F., and Haynes, R. J. (2011). Removal of Pb(II), Cr(III) and Cr(VI) from aqueous solutions using alum-derived water treatment sludge. Water, Air & Soil Pollution, 215, 631–643.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.