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Abstract

When applying the flotation process for phosphorus (P) removal in a lake, it is important to separate as much P as possible from water bodies and sediments using microbubbles. Furthermore, for removing P from the sediment, it is crucial to effectively remove readily releasable P that affects the growth of phytoplankton among various P forms. To find out the characteristics and behavior of various P forms in flotation, a series of experiments was carried out to classify and analyze various P types. This article explores how effectively the readily released P forms are separated from other P forms among various P forms in controlling P release from benthic sediment using the flotation separation process. Laboratory-scale dissolved air flotation (DAF) experiments were conducted to remove P from the water body and sediments collected from four brackish Saemangeum Lake sites. DAF could be applied owing to the improved P species composition (mobile P decrease), despite insufficient P removal efficiency in some areas. Moreover, to the best of our knowledge, this study is the first to apply DAF for the treatment of mobile P in sediments; further, the applicability of this process based on the P fractionation method is demonstrated. The findings of this study suggest that DAF removes mobile P contained in sediments more efficiently than immobile P and decreases the content of readily releasable P contained in some of the sediment particles that did not float and settle at the bottom.

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References

Anschutz

, Chaillou

, and Lecroart

(2007). Phosphorus diagenesis in sediment of the Thau Lagoon. Estuar. Coast. Shelf Sci. 72, 447.

Aulenbach

D.B.

, Shammas

N.K.

, Wang

L.K.

, and Kittler

R.D.I.

(2010). Lake restoration using dissolved air flotation. In: L. Wang, N. Shammas, W. Selke, and D. Aulenbach, Eds., Flotation Technology, Handbook of Environmental Engineering. Vol. 12. Totowa, NJ: Humana Press, p. 429.

Barik

S.K.

, Bramha

, Bastia

T. K.

, Behera

, Kumar

, Mohanty

P.K.

, and Rath

(2019). Characteristics of geochemical fractions of phosphorus and its bioavailability in sediments of a largest brackish water lake. South Asia Ecohydrol. Hydrobiol. 19, 370.

Boström

(1984). Potential mobility of phosphorus in different types of lake sediments. Int. Rev. Hydrobiol. 69, 457.

Chambers

R.M.

, Fourqurean

J.W.

, Hollibaugh

J.T.

, and Vink

S.M.

(1995). Importance of terrestrially-derived particulate phosphorus to phosphorus dynamics in a West Coast Estuary. Estuaries, 18, 518.

Edzwald

J.K.

(2010). Dissolved air flotation and me. Water Res. 44, 2077.

Gao

, Zhou

J.M.

, Yang

, and Chen

(2005). Phosphorus fractions in sediment profiles and their potential contributions to eutrophication in Dianchi Lake. Environ. Geol. 48, 835.

Gonsiorczyk

, Casper

, and Koschel

(1998). Phosphorus binding forms in the sediment of an oligotrophic and an eutrophic hardwater lake of the Baltic district (Germany). Water Sci. Technol. 37, 51.

Hieltjes

A.H.M.

, and Lijklema

(1980). Fractionation of inorganic phosphates in calcareous sediments. J. Environ. Qual. 9, 405.

10.

Huang

, Fang

, He

, Jiang

, and Wang

(2016). Effects of internal loading on phosphorus distribution in the Taihu Lake driven by wind waves and lake currents. Environ. Pollut. 219, 760.

11.

Jensen

H.S.

, Kristensen

, Jeppesen

, and Skytthe

(1992). Iron: Phosphorus ratio in surface sediment as an indicator of phosphate release from aerobic sediments in shallow lakes. Hydrobiology 235/236, 731.

12.

Jensen

H.S.

, Mortensen

P.B.

, Andersen, F.ⵁ., Rasmussen

, and Jensen

(1995). Phosphorus cycling in a coastal marine sediment, Aarhus Bay, Denmark. Limnol. Oceanogr. 40, 908.

13.

Jensen

H.S.

, and Thamdrup

(1993). Iron-bound phosphorus in marine sediments as measured by bicarbonate-dithionite extraction. Hydrobiologia, 253, 47.

14.

Jeong

H.J

, Kim

C.S.

, and Yang

J.S.

(2014). Estimation of addition and removal processes of nutrients from bottom water in the Saemangeum salt-water lake by using mixing model. J. Korean Soc. Mar. Environ. Energy, 17, 306.

15.

Kang

S.Y.

, Kim

H.J.

, Kim

T.I.

, Park

H.J.

, Na

C.K.

, and Han

M.Y.

(2016). Remediation of sediments using micro-bubbles. J. Korean Soc. Environ. Eng. 38, 420.

16.

Kim

S.H.

, Kim

, Lee

, Jeong

H.J.

, Kim

W.J.

, Park

J.G.

, and Yang

J.S.

(2009). Enhanced benthic nutrient flux during monsoon periods in a coastal lake formed by tideland reclamation. Estuar. Coast. 32, 1165.

17.

Kim

S.K.

, Ahn

J.H.

, Yun

S.L.

, Kang

S.W.

, Lee

J.K.

, Lim

J.-H.

, Kim

D.-S.

, and Lee

T.Y.

(2013). Removal of sediments below breeding ground using supersonics and micro-air flotation. J. Korean Soc. Environ. Eng. 35, 737.

18.

Kopáček

, Borovec

, Hejzlar

, Ulrich

K.-U.

, Norton

S.A.

, and Amirbahman

(2005). Aluminum control of phosphorus sorption by lake sediments. Environ. Sci. Technol. 39, 8784.

19.

Kozerski

H.P.

, and Kleeberg

(1998). The sediments and benthic pelagic exchange in the shallow lake Müggelsee. Int. Rev. Hydrobiol. 83, 77.

20.

Kuster

A.C.

, Kuster

A.T.

, and Huser

B.J.

(2020). A comparison of aluminum dosing methods for reducing sediment phosphorus release in lakes. J. Environ. Manage. 261, 110195.

21.

Kwak

D.H.

, Jeon

Y.T.

, and Hur

Y.D.

(2018). Phosphorus fractionation and release characteristics of sediment in the Saemangeum Reservoir for seasonal change. Int. J. Sediment Res. 33, 250.

22.

Lü

, Wang

B. H

e, J., Vogt

R.D.

, Zhou

, Guan

, Zuo

, Wang

, Xie

, Wang

, and Yan

(2016). Responses of organic phosphorus fractionation to environmental conditions and lake evolution, Environ. Sci. Technol. 50, 5007.

23.

Mesnage

, and Picot

(1995). The distribution of phosphate in sediments and its relationship with eutrophication of the Mediterranean Coastal Lagoon. Hydrobiologia, 297, 29.

24.

, Wang

, Wu

, and Pu

(2020). Response of phosphorus fractionation in lake sediments to anthropogenic activities in China. Sci. Total Environ. 699, 134242.

25.

Ruttenberg

K.C.

(1992). Development of a sequential extraction method for different forms of phosphorus in marine sediments. Limnol. Oceanogr. 37, 1460.

26.

Ruttenberg

K.C.

(1993). Reassessment of the oceanic residence time of phosphorus. Chem. Geol. 107, 405.

27.

Schulz

H.D.

(2000). Quantification of early diagenesis: dissolved constituents in marine pore water. In H.D. Schulz, and M. Zabel, Eds. Marine Geochemistry. Berlin: Springer-Verlag, pp. 85–128.

28.

Shin

Y.R.

, Jung

J.Y.

, Choi

J.H.

, and Jung

K.W.

(2012). Hydrodynamic modeling of Saemangeum reservoir and watershed using HSPF and EFDC. J. Korean Soc. Water Environ. 28, 384.

29.

Sø

H.U.

, Postma

, Jakobsen

, and Larsen

(2011). Sorption of phosphate onto calcite; results from batch experiments and surface complexation modeling. Geochim. Cosmochim. Acta, 75, 2911.

30.

Wang

S.R.

, Jin

X.C.

, Bu

Q.Y.

, Zhou

X.N.

, and Wu

F.C.

(2006). Effects of particle size, organic matter, and ionic strength on phosphate sorption in different trophic lake sediments. J. Hazard. Mater. 128, 95.

31.

Zaaboub

, Ounis

, Helali

M.A.

, Béjaoui

, Lillebø

A.I.

, da Silva

E.F.

, and Aleya

(2014). Phosphorus speciation in sediments and assessment of nutrient exchange at the water–sediment interface in a Mediterranean lagoon: Implications for management and restoration. Ecol. Eng. 73, 115.

Dissolved Air Flotation to Control Phosphorus Release of Benthic Sediment in a Coastal Brackish Lake

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