Combined control of phosphorus release from sediment by red soil and Vallisneria spiralis
ZHANG Yu1,2, YIN Yue-peng1,2, TANG Jin-yong1,2, CAO Xi1,2, LIU Jing-jing1,2, ZHANG Wen1,2,3
1. College of Environment and Ecology, Chengdu University of Technology, Chengdu 610059, China; 2. National Key Laboratory for Coordinated Control and Remediation of Water and Soil Pollution in Environmental Protection (SEKL-SW), Chengdu 610059, China; 3. State Key Laboratory of Geological Disaster Prevention and Geological Environment Protection, Chengdu 610059, China
Abstract:The effect of single and combined remediation on phosphorus removal from polluted sediment was studied by using the in situ combined remediation technology of red soil and Vallisneria spiralis(RS +VS). The results showed that the removal capacity of sediment P by RS and VS combined remediation was higher than that by single remediation. In the 37d batch experiment, the phosphorus released from sediment in the RS+VS group was inhibited by 91%. Compared with the phosphorus released from sediment in the RS+VS group without coverage, the dissolved active phosphorus (SRP) in the overlying water decreased from 1.41mg/L to 0.12mg/L. RS+VS combined remediation had a significant effect on the fixation of sediment phosphorus, The unstable ferrous phosphorus (Fe(II)-P) and iron aluminum bound phosphorus (CDB-P) were transformed into inert calcium phosphorus (Ca-P). The content of Ca-P in sediment increased by 51%, while Fe(II)-P and CDB-P decreased by 1% and 24% respectively, effectively reducing the risk of phosphorus release from sediment to overlying water. In conclusion, RS+VS combination can be applied to treat the internal phosphorus load in eutrophic waters to realize the coordinated removal of sediment phosphorus. At the same time, RS and VS are cheap and widely distributed, and can be used as a potential high-benefit phosphate adsorbent in practical projects.
张瑜, 尹月鹏, 唐金勇, 曹熙, 刘晶京, 张雯. 天然红土与苦草联合控制沉积物中磷释放[J]. 中国环境科学, 2022, 42(8): 3728-3735.
ZHANG Yu, YIN Yue-peng, TANG Jin-yong, CAO Xi, LIU Jing-jing, ZHANG Wen. Combined control of phosphorus release from sediment by red soil and Vallisneria spiralis. CHINA ENVIRONMENTAL SCIENCECE, 2022, 42(8): 3728-3735.
Colborne S F, Maguire T J, Mayer B, et al. Water and sediment as sources of phosphate in aquatic ecosystems:The Detroit River and its role in the Laurentian Great Lakes[J]. Science of the Total Environment, 2019,647:1594-1603.
[2]
Ulen B, Bechmann M, Folster J, et al. Agriculture as a phosphorus source for eutrophication in the north-west European countries, Norway, Sweden, United Kingdom and Ireland:a review[J]. Soil Use and Management, 2007,23:5-15.
[3]
Ding S, Chen M, Gong M, et al. Internal phosphorus loading from sediments causes seasonal nitrogen limitation for harmful algal blooms[J]. Science of the Total Environment, 2018,625:872-884.
[4]
Wu Z, Liu Y, Liang Z, et al. Internal cycling, not external loading, decides the nutrient limitation in eutrophic lake:A dynamic model with temporal Bayesian hierarchical inference[J]. Water Res, 2017,116:231-240.
[5]
Horppila J. Sediment nutrients, ecological status and restoration of lakes[J]. Water Research, 2019,160:206-208.
[6]
Horppila J, Holmroos H, Niemisto J, et al. Variations of internal phosphorus loading and water quality in a hypertrophic lake during 40years of different management efforts[J]. Ecological Engineering, 2017,103:264-274.
[7]
万杰,袁旭音,叶宏萌,等.洪泽湖不同入湖河流沉积物磷形态特征及生物有效性[J]. 中国环境科学, 2020,40(10):4568-4579. Wan J, Yuan X, Ye H, et al. Characteristics and bioavailability of different forms of phosphorus in sediments of rivers flowing into Hongze Lake[J]. China Environmental Science, 2020,40(10):4568-4579.
[8]
Huang J, Zhang Y, Arhonditsis G B, et al. How successful are the restoration efforts of China's lakes and reservoirs?[J]. Environment International, 2019,123:96-103.
[9]
Paytan A, Roberts K, Watson S, et al. Internal loading of phosphate in Lake Erie Central Basin[J]. Science of the Total Environment, 2017, 579:1356-1365.
[10]
Lurling M, Mackay E, Reitzel K, et al. Editorial-A critical perspective on geo-engineering for eutrophication management in lakes[J]. Water Research, 2016,97:1-10.
[11]
Wilfert P, Mandalidis A, Dugulan A I, et al. Vivianite as an important iron phosphate precipitate in sewage treatment plants[J]. Water Research, 2016,104:449-460.
[12]
Yuan Z, Jiang S, Sheng H, et al. Human perturbation of the global phosphorus cycle:Changes and consequences[J]. Environmental Science & Technology, 2018,52(5):2438-2450.
[13]
Pineyro M, Chalar G, Quintans F. Constructed wetland scale model:organic matter and nutrients removal from the effluent of a fish processing plant[J]. International Journal of Environmental Science and Technology, 2019,16(8):4181-4192.
[14]
Yu J, Ding S, Zhong J, et al. Evaluation of simulated dredging to control internal phosphorus release from sediments:Focused on phosphorus transfer and resupply across the sediment-water interface[J]. Science of the Total Environment, 2017,592:662-673.
[15]
Yin H, Yang C, Yang P, et al. Contrasting effects and mode of dredging and in situ adsorbent amendment for the control of sediment internal phosphorus loading in eutrophic lakes[J]. Water Research, 2021,189(17):116.
[16]
Xu D, Ding S, Sun Q, et al. Evaluation of in situ capping with clean soils to control phosphate release from sediments[J]. Science of the Total Environment, 2012,438:334-341.
[17]
Xiong C, Wang D, Tam N F, et al. Enhancement of active thin-layer capping with natural zeolite to simultaneously inhibit nutrient and heavy metal release from sediments[J]. Ecological Engineering, 2018,119:64-72.
[18]
Luo P, Liu F, Zhang S, et al. Nitrogen removal and recovery from lagoon-pretreated swine wastewater by constructed wetlands under sustainable plant harvesting management[J]. Bioresource Technology, 2018,258:247-254.
[19]
孔祥龙,叶春,李春华,等.苦草对水-底泥-沉水植物系统中氮素迁移转化的影响[J]. 中国环境科学, 2015,35(2):539-549. Kong X, Ye C, Li C, et al. Effect on nitrogen transfer and migration by Vallisneria nutans (Lour.) Hara in water-sediment-submerged macrophytes system[J]. China Environmental Science, 2015,35(2):539-549.
[20]
Human L R D, Snow G C, Adams J B, et al. The role of submerged macrophytes and macroalgae in nutrient cycling:A budget approach[J]. Estuarine Coastal and Shelf Science, 2015,154:169-178.
[21]
Wang L, Sun J, Zheng W, et al. Effects of a combined biological restoration technology on nitrogen and phosphorus removal from eutrophic water[J]. Polish Journal of Environmental Studies, 2018,27(5):2293-2301.
[22]
Liu Z, Hu J, Zhong P, et al. Successful restoration of a tropical shallow eutrophic lake:Strong bottom-up but weak top-down effects recorded[J]. Water Research, 2018,146:88-97.
[23]
Yenilmez F, Aksoy A. Comparison of phosphorus reduction alternatives in control of nutrient concentrations in Lake Uluabat (Bursa, Turkey):Partial versus full sediment dredging[J]. Limnologica, 2013,43(1):1-9.
[24]
Huser B J, Egemose S, Harper H, et al. Longevity and effectiveness of aluminum addition to reduce sediment phosphorus release and restore lake water quality[J]. Water Research, 2016,97:122-132.
[25]
Yin H, Zhu J. In situ remediation of metal contaminated lake sediment using naturally occurring, calcium-rich clay mineral-based low-cost amendment[J]. Chemical Engineering Journal, 2016,285:112-120.
[26]
Lin J, Zhan Y, Zhu Z. Evaluation of sediment capping with active barrier systems (ABS) using calcite/zeolite mixtures to simultaneously manage phosphorus and ammonium release[J]. Science of the Total Environment, 2011,409(3):638-646.
[27]
Zhang L, Hong S, He J, et al. Adsorption characteristic studies of phosphorus onto laterite[J]. Desalination and Water Treatment, 2011, 25(1-3):98-105.
[28]
Kpannieu D E, Mallet M, Coulibaly L, et al. Phosphate removal from water by naturally occurring shale, sandstone, and laterite:The role of iron oxides and of soluble species[J]. Comptes Rendus Geoscience, 2019,351(1):37-47.
[29]
Sarkar M, Banerjee A, Pramanick P P, et al. Use of laterite for the removal of fluoride from contaminated drinking water[J]. Journal of Colloid and Interface Science, 2006,302(2):432-441.
[30]
Coulibaly L S, Akpo S K, Yvon J, et al. Fourier transform infra-red (FTIR) spectroscopy investigation, dose effect, kinetics and adsorption capacity of phosphate from aqueous solution onto laterite and sandstone[J]. Journal of Environmental Management, 2016,183:1032-1040.
[31]
Gu B-W, Hong S-H, Lee C-G, et al. The feasibility of using bentonite, illite, and zeolite as capping materials to stabilize nutrients and interrupt their release from contaminated lake sediments[J]. Chemosphere, 2019,219:217-226.
[32]
Ajmal Z, Muhmood A, Usman M, et al. Phosphate removal from aqueous solution using iron oxides:Adsorption, desorption and regeneration characteristics[J]. Journal of Colloid and Interface Science, 2018,528:145-155.
[33]
Zhu T, Cao T, Ni L, et al. Improvement of water quality by sediment capping and re-vegetation with Vallisneria natans L.:A short-term investigation using an in situ enclosure experiment in Lake Erhai, China[J]. Ecological Engineering, 2016,86:113-119.
[34]
Rezania S, Taib S M, Din M F M, et al. Comprehensive review on phytotechnology:Heavy metals removal by diverse aquatic plants species from wastewater[J]. Journal of Hazardous Materials, 2016,318:587-599.
[35]
Li Y, Wang L G, Chao C X, et al. Submerged macrophytes successfully restored a subtropical aquacultural lake by controlling its internal phosphorus loading[J]. Environmental Pollution, 2021,268:115.
[36]
Soana E, Naldi M, Bartoli M. Effects of increasing organic matter loads on pore water features of vegetated (Vallisneria spiralis L.) and plant-free sediments[J]. Ecological Engineering, 2012,47:141-145.
[37]
Sand-Jensen K, Bruun H H, Baastrup-Spohr L. Decade-long time delays in nutrient and plant species dynamics during eutrophication and re-oligotrophication of Lake Fure 1900-2015[J]. Journal of Ecology, 2017,105(3):690-700.
[38]
Horppila J, Nurminen L. Effects of submerged macrophytes on sediment resuspension and internal phosphorus loading in Lake Hiidenvesi (southern Finland)[J]. Water Research, 2003,37(18):4468-4474.
[39]
Xie Y H, An S Q, Wu B F. Resource allocation in the submerged plant Vallisneria natans related to sediment type, rather than water-column nutrients[J]. Freshwater Biology, 2005,50(3):391-402.
[40]
Gu S, Qian Y, Jiao Y, et al. An innovative approach for sequential extraction of phosphorus in sediments:Ferrous iron P as an independent P fraction[J]. Water Research, 2016,103:352-361.
[41]
刘子森,张义,王川,等.改性膨润土和沉水植物联合作用处理沉积物磷[J]. 中国环境科学, 2018,38(2):665-674. Liu Z, Zhang Y, Wang C, et al. Synergistic removal of sediment P by combining the modified bentonite and Vallisneria spiralis[J]. China Environmental Science, 2018,38(2):665-674.
[42]
Tu L, Jarosch K A, Schneider T, et al. Phosphorus fractions in sediments and their relevance for historical lake eutrophication in the Ponte Tresa basin (Lake Lugano, Switzerland) since 1959[J]. Science of the Total Environment, 2019,685:806-817.
[43]
黎睿,王圣瑞,肖尚斌,等.长江中下游与云南高原湖泊沉积物磷形态及内源磷负荷[J]. 中国环境科学, 2015,35(6):1831-1839. Li R, Wang S, Xiao S, et al. Sediments phosphorus forms and loading in the lakes of the mid-lower reaches of the Yangtze River and Yunnan Plateau, China[J]. China Environmental Science, 2015,35(6):1831-1839.
[44]
Xing X, Ding S, Liu L, et al. Direct evidence for the enhanced acquisition of phosphorus in the rhizosphere of aquatic plants:A case study on Vallisneria natans[J]. Science of the Total Environment, 2018,616:386-396.
[45]
Zeng W, Ren X, Shen L, et al. Effects of consecutive culture of Penaeus vannamei on phosphorus transformation and microbial community in sediment[J]. Environmental Science and Pollution Research, 2021,28(39):55716-55724.