欢迎登录材料期刊网

材料期刊网

高级检索

采用自行研发的泥?水界面微孔曝气系统,开展了底泥表面曝气和覆盖对城市重污染河道底泥磷释放及形态分布规律的影响研究.结果表明,微孔曝气能够有效提高上覆水的溶解氧( DO)和沉积物的氧化还原电位( Eh),能够将泥?水界面Eh维持在-100 mV左右,DO提高到6 mg·L-1以上.与对照比较,原位覆盖处理的上覆水DO和Eh有一定提高,但仍明显低于微孔曝气处理.与对照相比较,微孔曝气处理均有效降低上覆水中总磷(TP)和溶解性正磷酸盐(PO3-4)的含量.试验结束时,微孔曝气(A)和微孔曝气+原位覆盖处理(A+C)上覆水中TP 含量由初始的0.201 mg·L-1分别降至0.062 mg·L-1和0.050 mg·L-1;上覆水中 PO3-4含量由0.086 mg·L-1和0.078 mg·L-1分别降至0.026 mg·L-1和0.023 mg·L-1.与对照相比,微孔曝气处理明显降低了底泥间隙水中TP的浓度,在整个培养期间,其TP含量平均下降38.8%(A)和47.9%(A+C).底泥原位覆盖处理对抑制泥?水界面磷释放能力要弱于微孔曝气处理,而且在试验后期(50 d),上覆水中TP和PO3-4的含量均有所反弹.不管有无覆盖,泥?水界面微孔曝气处理均显著改变了表层底泥磷形态分布特征,显著降低了底泥中铁铝结合态磷( Fe/Al?P )组分比例,而钙结合态磷( Ca?P )含量比例却出现明显增加.单一的表面覆盖处理对底泥磷形态分布特征没有显著影响( P>0.05).研究表明,与单一的处理效果相比较,泥?水界面纳米微孔曝气处理,并结合底泥原位覆盖,更有利于抑制城市重污染河道泥?水界面中磷的释放风险.

A simulation experiment with precision oxygen distribution system was conducted to study the effect of fine bubble aeration and capping on sediment?water interface on species distributions and release potential of phosphorus in the sediment sampled from a heavily polluted urban river in Hefei City, Anhui Province. The results showed that the concentration of dissolved oxygen ( DO) in the overlying water and the redox potential ( Eh ) of the sediment?water interface had been significantly increased with the use of the bubble aeration device and were maintained at about 6 mg·L-1 and -100 mV respectively. Compared with the control, the capping treatment increase the Eh and DO of sediment?water interface, but the effectiveness was significantly lower relative to bubble aeration treatments. The treatments with bubble aeration had positive effects in reducing the concentration of total phosphorus (TP) and dissolved orthophosphate (PO3-4 ) in overlying water. At the end of the experiment, the concentrations of TP in overlying water dropped from 0.201 mg·L-1 to 0.062 mg·L-1 for single bubble aeration (A) and 0.050 mg·L-1 for bubble aeration with capping treatment ( A+C) , and PO3-4 from 0.086 mg·L-1 and 0.078 mg·L-1 to 0.026 mg·L-1( A) and 0?023 mg·L-1 ( A+C ) , respectively. Compared with the control, the aeration treatments significantly decreased the concentration of TP with an average reduction of 38.8% for A treatment and 47.9% for A+C treatment during the experiment, respectively. Although capping treatment ( C) inhibited the release potential of phosphorus in sediment?water interface as compared with the control, the inhibitory efficiency was significantly weaker relative to the fine bubble aeration treatments. Even at the end of the experiment, the concentrations of TP and PO3-4 in the overlying water for capping treatment rebounded. Regardless of capping or not, the fine bubble aeration on sediment?water interface significantly changed the distribution of phosphorus species in surface sediment, and decreased Fe/Al?bound phosphorus ( Fe/Al?P ) fraction, but significantly increased Ca?bound phosphorus fraction. The capping treatment showed little effect on the distributions of phosphorus species. Our study implies that the fine bubble aeration combined with in situ capping on sediment?water interface can more effectively inhibit the release risk of phosphorus from sediment to overlying water from a heavily polluted urban river, as compared with the corresponding single treatment.

参考文献

[1] Alexander R B;Smith R A .Trends in the nutrient enrichment of US rivers during the late 20th century and their relation to changes in probable stream trophic conditions[J].Limnology and Oceanography,2006,51(1):639-654.
[2] 金相灿,王圣瑞,庞燕.太湖沉积物磷形态及pH值对磷释放的影响[J].中国环境科学,2004(06):707-711.
[3] Hickey C W;Gibbs M M .Lake sediment phosphorus release management-Decision support and risk assessment framework. New Zealand[J].Jounal of Marine and Freshwater Research,2009,43(3):819-854.
[4] Ogdahl M E;Steinman A D;Weinert M E .Laboratory-determined phosphorus flux from lake sediments as a measure of internal phosphorus loading[J].Journal of Visualized Experiments,2014,85:51617.
[5] Su J J;van Bochove E;Auclair J C et al.Phosphorus fluxes at the sediment-water interface in a temperate region agricultural catchment[J].Water,Air,and Soil Pollution,2014,225:1739-1749.
[6] 黄廷林,周瑞媛,夏超,徐金兰.氧化还原电位及微生物对水库底泥释磷的影响[J].环境化学,2014(06):930-936.
[7] Hupfer M;Lewandowski J .Oxygen Controls the Phosphorus Release from Lake Sediments - a Long-Lasting Paradigm in Limnology[J].International review of hydrobiology,2008(4/5):415-432.
[8] 孙士权,邱嫒,蒋昌波,杨静,聂小保,谭万春,吴方同.原位技术控制湖泊沉积物中磷释放的研究[J].中国环境科学,2011(05):845-851.
[9] 周莹,潘纲,陈灏.土壤原位覆盖对底泥的修复作用研究[J].环境工程学报,2011(11):2459-2463.
[10] Gerard Cornelissen;Marie Elmquist Krusa;Gijs D. Breedveld .Remediation of Contaminated Marine Sediment Using Thin-Layer Capping with Activated Carbon—A Field Experiment in Trondheim Harbor, Norway[J].Environmental Science & Technology: ES&T,2011(14):6110-6116.
[11] Ottolenghi F;Qin JG;Mittiga L .Enhancement of phosphorus release from lake sediments by aeration and crayfish activity[J].Journal of Freshwater Ecology,2002(4):635-640.
[12] Jianjun Chen,Shaoyong Lu,Yikun Zhao,Wei Wang,Minsheng Huang.Effects of overlying water aeration on phosphorus fractions and alkaline phosphatase activity in surface sediment[J].环境科学学报(英文版),2011(02):206-211.
[13] 林建伟,朱志良,赵建夫.曝气复氧对富营养化水体底泥氮磷释放的影响[J].生态环境,2005(06):812-815.
[14] 刘波,王国祥,王风贺,杜旭,凌芬,夏劲.不同曝气方式对城市重污染河道水体氮素迁移与转化的影响[J].环境科学,2011(10):2971-2978.
[15] Kevin G. Taylor;Philip N. Owens .Sediments in urban river basins: a review of sediment-contaminant dynamics in an environmental system conditioned by human activities[J].Journal of soil & sediments,2009(4):281.
[16] Ruban V;Brigault S;Demare D .An investigation of the origin and mobility of phosphorus in freshwater sediments from Bort-Les-Orgues Reservoir, France[J].Journal of Environmental Monitoring,1999,1(4):403-407.
[17] Li Da-Peng;Huang Yong .Sedimentary phosphorus fractions and bioavailability as influenced by repeated sediment resuspension[J].Ecological engineering: The Journal of Ecotechnology,2010(7):958-962.
[18] Miao SY;DeLaune RD;Jugsujinda A .Influence of sediment redox conditions on release/solubility of metals and nutrients in a Louisiana Mississippi River deltaic plain freshwater lake[J].Science of the Total Environment,2006(1/3):334-343.
[19] Effler S W;Matthews D A .Implications of redox processes for the rehabilitation of an urban lake,Onondaga Lake,New York[J].Lake and Reservoir Management,2009,24:2,122-138.
[20] Lukkari, K.;Leivuori, M.;Kotilainen, A. .The chemical character and behaviour of phosphorus in poorly oxygenated sediments from open sea to organic-rich inner bay in the Baltic Sea[J].Biogeochemistry,2009(1/3):25-48.
[21] Kowalczewska-Madura, K.;Go?dyn, R.;Dondajewska, R. .Phosphorus release from the bottom sediments of Lake Rusa?ka (Poznań, Poland)[J].Oceanological and hydrobiological studies,2010(4):135-144.
[22] 李大鹏,黄勇.溶解氧对底泥扰动状态下水体中磷去除和固定的影响[J].环境工程学报,2013(10):3785-3790.
[23] Makiko L;Takayuki N .Suppression of phosphorus release from sediments using water clarifier sludge as capping material[J].Environmental Technology,34(15):2291-2299.
[24] Galina Kapanen .Pool of mobile and immobile phosphorus in sediments of the large, shallow Lake Peipsi over the last 100 years[J].Environmental Monitoring and Assessment: An International Journal,2012(11):6749-6763.
[25] Gao L;Zhang L H;Shao H B .Phosphorus bioavailability and release potential risk of the sediments in the coastal wetland:A case study of Rongcheng Swan Lake, Shandong, China[J].Clean-Soil, Air and Water,2014,42(7):963-972.
[26] G. Martins;L. Peixoto;S. Teodorescu;P. Parpot;R. Nogueira;A.G. Brito.Impact of an external electron acceptor on phosphorus mobility between water and sediments[J].Bioresource Technology: Biomass, Bioenergy, Biowastes, Conversion Technologies, Biotransformations, Production Technologies,2014:419-423.
[27] Li H Y;Liu L;Li M Y.Effects of pH, temperature, dissolved oxygen, and flow rate on phosphorus release processes at the sediment and water interface in storm sewer[J].Journal of Analytical Methods in Chemistry,2013
[28] Yunhai Wu;Yajun Wen;Jianxin Zhou;Yunying Wu .Phosphorus Release from Lake Sediments: Effects of pH, Temperature and Dissolved Oxygen[J].KSCE journal of civil engineering,2014(1):323-329.
上一张 下一张
上一张 下一张
计量
  • 下载量()
  • 访问量()
文章评分
  • 您的评分:
  • 1
    0%
  • 2
    0%
  • 3
    0%
  • 4
    0%
  • 5
    0%