潜流带胶体特征及对生源要素迁移的影响机制
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摘要
为深入了解潜流带中胶体物质特征及对生源要素循环的影响,综合阐述近年来国内外在含水介质胶体物质特征及对生源要素吸附、迁移、转化和交换等方面的研究进展,包括:(a)地表水-地下水交互下潜流带中胶体物质来源、组分、时空分布和释放迁移特性;(b)潜流带物理、化学和生物条件等变化对胶体物质特性的影响;(c)潜流带生源要素分布和迁移与胶体物质特征的关系;(d)含水介质中胶体物质及其携带生源要素迁移转化方程模式的合理性。结合当前研究动态提出潜流带胶体物质对生源要素迁移影响研究中存在的问题并对研究进行展望。
For better understanding the characteristics of colloidal substance and its effect on biogenic element cycle in the hyporheic zone, this review focuses on recent advances of adsorption, release, migration, transformation, and exchange of biogenic elements influenced by colloidal substances. Main content of this review include:(a) the source, composition, temporal-spatial distribution, release, and migration of colloidal substance in the hyporheic zone under the interaction of surface water and groundwater;(b) the effects of physical, chemical, and biological conditions of the hyporheic zone on the properties of colloidal substance;(c) relationship between the distribution of biogenic elements in the hyporheic zone and the influencing mechanism of colloid facilitated-transport of biogenic elements;(d) rationality of present mathematical models for the migration and transformation of colloidal substance and its facilitated-transport of biogenic elements. Some research prospects are proposed based on present trends and deficiencies of researches about the influence of colloidal substances on the transport and transformation of biological elements in the hyporheic zone.
For better understanding the characteristics of colloidal substance and its effect on biogenic element cycle in the hyporheic zone, this review focuses on recent advances of adsorption, release, migration, transformation, and exchange of biogenic elements influenced by colloidal substances. Main content of this review include:(a) the source, composition, temporal-spatial distribution, release, and migration of colloidal substance in the hyporheic zone under the interaction of surface water and groundwater;(b) the effects of physical, chemical, and biological conditions of the hyporheic zone on the properties of colloidal substance;(c) relationship between the distribution of biogenic elements in the hyporheic zone and the influencing mechanism of colloid facilitated-transport of biogenic elements;(d) rationality of present mathematical models for the migration and transformation of colloidal substance and its facilitated-transport of biogenic elements. Some research prospects are proposed based on present trends and deficiencies of researches about the influence of colloidal substances on the transport and transformation of biological elements in the hyporheic zone.
引文
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[35] JIANG Canlan,SéQUARIS J M,VEREECKEN H.Effects of temperature and associated organic carbon on the fractionation of water-dispersible colloids from three silt loam topsoils under different land use[J].Geoderma,2017,299:43-53.
[36] TORKZABAN S,KIM H N,SIMUNEK J,et al.Hysteresis of colloid retention and release in saturated porous media during transients in solution chemistry[J].Environmental Science & Technology,2010,44(5):1662-1669.
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[44] SANTOSA I R,HUETTEL M.The driving forces of porewater and groundwater flow in permeable coastal sediments:a review[J].Estuarine Coastal & Shelf Science,2012,98(1):1-15.
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[ 2 ] MOLNAR I L,JOHNSON W P,GERHARD J I,et al.Predicting colloid transport through saturated porous media:a critical review[J].Water Resources Research,2015,51(9):6804-6845.
[ 3 ] SEN T K.Processes in pathogenic biocolloidal contaminants transport in saturated and unsaturated porous media:a review[J].Water Air & Soil Pollution,2011,216(1/2/3/4):239-256.
[ 4 ] CLOUGH T J,CONDRON L M,KAMMANN C,et al.A review of biochar and soil nitrogen dynamics[J].Agronomy,2013,3(2):275-293.
[ 5 ] SEN T K,KHILAR K C.Review on subsurface colloids and colloid-associated contaminant transport in saturated porous media[J].Advances in Colloid & Interface Science,2006,119(2):71-96.
[ 6 ] 滕彦国,左锐,王金生.地表水-地下水的交错带及其生态功能[J].地球与环境,2007,35(1):1-8.(TENG Yanguo,ZUO Rui,WANG Jinsheng.Hyporheic zone of groundwater and surface water and its ecological function[J].Earth & Environment,2007,35(1):1-8.(in Chinese))
[ 7 ] BOANO F,HARVEY J W,MARION A,et al.Hyporheic flow and transport processes:mechanisms,models,and biogeochemical implications[J].Reviews of Geophysics,2014,52(4):603-679.
[ 8 ] LI Yong,WANG Shuang,ZHANG Weiwei,et al.Potential drivers of the level and distribution of nitrogen in the hyporheic zone of Lake Taihu,China[J].Water,2017,9(7):544.
[ 9 ] PACIOGLU O.Ecology of the hyporheic zone:a review[J].Cave and Karst Science,2010,36(3):69-76.
[10] 李勇,张维维,袁佳慧,等.潜流带水流特性及氮素运移转化研究进展[J].河海大学学报(自然科学版),2016,44(1):1-7.(LI Yong,ZHANG Weiwei,YUAN Jiahui,et al.Research advances in flow patterns and nitrogen transformation in hyporheic zones[J].Journal of Hohai University (Natural Sciences),2016,44 (1):1-7.(in Chinese))
[11] LIU Ziru,FLURY M,HARSH J B,et al.Colloid mobilization in an undisturbed sediment core under semiarid recharge rates[J].Water Resources Research,2013,49(8):4985-4996.
[12] YAO Suchun,XUE Bin.Nutrients and heavy metals in multi-cores from Zhushan Bay at Taihu Lake,the largest shallow lake in the Yangtze Delta,China[J].Quaternary International,2010,226:23-28.
[13] GROLIMUND D,BORKOVEC M.Release of colloidal particles in natural porous media by monovalent and divalent cations[J].Journal of Contaminant Hydrology,2006,87(3):155-175.
[14] DE JONGE L W,KJAERGAARD C,MOLDRUP P.Colloids and colloid-facilitated transport of contaminants in soils[J].Vadose Zone Journal,2004,3(2):321-325.
[15] BOEHME J,WELLS M.Fluorescence variability of marine and terrestrial colloids:examining size fractions of chromophoric dissolved organic matter in the Damariscotta River estuary[J].Marine Chemistry,2006,101(1):95-103.
[16] WIKINIYADHANEE R,CHOTPANTARAT S,ONG S K.Effects of kaolinite colloids on Cd2+ transport through saturated sand under varying ionic strength conditions:column experiments and modeling approaches[J].Journal of Contaminant Hydrology,2015,182:146-156.
[17] LI Zaoli,ZHOU Lixiang.Cadmium transport mediated by soil colloid and dissolved organic matter:a field study[J].Journal of Environmental Sciences,2010,22(1):106-115.
[18] QIAN Kun,LI Junxia,XIE Xianjun,et al.Organic and inorganic colloids impacting total iodine behavior in groundwater from the Datong Basin,China[J].Science of the Total Environment,2017,601/602:380-390.
[19] DE JONGE L W,MOLDRUP P,RUB?G H,et al.Particle leaching and particle-facilitated transport of phosphorus at field scale[J].Vadose Zone Journal,2004,3(2):462-470.
[20] YANG Wen,WANG Yang,SHARMA P,et al.Effect of naphthalene on transport and retention of biochar colloids through saturated porous media[J].Colloids and Surfaces A(Physicochemical and Engineering Aspects),2017,530:146-154.
[21] SANGSTER J L,OKE H,ZHANG Yun,et al.The effect of particle size on sorption of estrogens,androgens and progestagens in aquatic sediment[J].Journal of Hazardous Materials,2015,299:112-121.
[22] FUJITA T,SUGIYAMA D,SWANTON S W,et al.Observation and characterization of colloids derived from leached cement hydrates[J].Journal of Contaminant Hydrology,2003,61(1):3-16.
[23] QUIK J T K,STUART M C,WOUTERSE M,et al.Natural colloids are the dominant factor in the sedimentation of nanoparticles[J].Environmental Toxicology and Chemistry,2012,31(5):1019-1022.
[24] GROLIMUND D,BORKOVEC M.Colloid-facilitated transport of strongly sorbing contaminants in natural porous media:mathematical modeling and laboratory column experiments[J].Environmental Science & Technology,2005,39(17):6378-6386.
[25] ZHANG Wei,TANG Xiangyu,WEISBROD N,et al.A coupled field study of subsurface fracture flow and colloid transport[J].Journal of Hydrology,2015,524:476-488.
[26] PATIL S,TAWFIQ K,CHEN G.Colloid release and transport in agricultural soil as impacted by solution chemistry[J].Journal of Urban & Environmental Engineering,2011,5(2):84-90.
[27] BRADFORD S A,TORKZABAN S,LEIJ F,et al.Equilibrium and kinetic models for colloid release under transient solution chemistry conditions[J].Journal of Contaminant Hydrology,2015,181:141-152.
[28] BRADFORD S A,BETTAHAR M,SIMUNEK J,et al.Straining and attachment of colloids in physically heterogeneous porous media[J].Vadose Zone Journal,2004,3(2):384-394.
[29] MITROPOULOU P N,SYNGOUNA V I,CHRYSIKOPOULOS C V.Transport of colloids in unsaturated packed columns:role of ionic strength and sand grain size[J].Chemical Engineering Journal,2013,232:237-248.
[30] MISHUROV M,YAKIREVICH A,WEISBROD N.Colloid transport in a heterogeneous partially saturated sand column[J].Environmental Science & Technology,2008,42(4):1066-1071.
[31] CHENG Tao,SAIERS J E.Colloid-facilitated transport of cesium in vadose-zone sediments:the importance of flow transients[J].Environmental Science & Technology,2010,44(19):7443-7449.
[32] SHANG Jianying,FLURY M,CHEN Gang,et al.Impact of flow rate,water content,and capillary forces on in situ colloid mobilization during infiltration in unsaturated sediments[J].Water Resources Research,2008,44(6):376-380.
[33] RYAN J N,ILLANGASEKARE T H,LITAOR M I,et al.Particle and plutonium mobilization in macroporous soils during rainfall simulations[J].Environmental Science & Technology,1998,32(4):476-482.
[34] M?RI A,ALEXANDER W R,GECKEIS H,et al.The colloid and radionuclide retardation experiment at the Grimsel Test Site:influence of bentonite colloids on radionuclide migration in a fractured rock[J].Colloids and Surfaces A(Physicochemical and Engineering Aspects),2003,217(1):33-47.
[35] JIANG Canlan,SéQUARIS J M,VEREECKEN H.Effects of temperature and associated organic carbon on the fractionation of water-dispersible colloids from three silt loam topsoils under different land use[J].Geoderma,2017,299:43-53.
[36] TORKZABAN S,KIM H N,SIMUNEK J,et al.Hysteresis of colloid retention and release in saturated porous media during transients in solution chemistry[J].Environmental Science & Technology,2010,44(5):1662-1669.
[37] LI Haiming,WEI Wei,GE Yachao,et al.The influence of Na+and Ca2+ on the migration of colloids or/and ammonia nitrogen in an unsaturated zone medium[J].Journal of Contaminant Hydrology,2016,194:24-29.
[38] YANG Wen,WANG Yanxin,SHANG Jianying,et al.Antagonistic effect of humic acid and naphthalene on biochar colloid transport in saturated porous media[J].Chemosphere,2017,189:556-564.
[39] HU Caohua,ZHANG Youchi,LUO Wensui.Retention effects of soil humic substances on the diffusive transportation of metal ions during sediment porewater membrane dialysis sampling[J].Water Air & Soil Pollution,2013,224(6):1-9.
[40] MORALES V L,ZHANG Wei,GAO Bin,et al.Impact of dissolved organic matter on colloid transport in the vadose zone:deterministic approximation of transport deposition coefficients from polymeric coating characteristics[J].Water Research,2011,45(4):1691-1701.
[41] POKROVSKY O S,DUPRéB,SCHOTT J.Fe-Al-organic colloids control of trace elements in peat soil solutions:results of ultrafiltration and dialysis[J].Aquatic Geochemistry,2005,11(3):241-278.
[42] PI Kunfu,WANG Yanxin,XIE Xianjun,et al.Hydrogeochemistry of co-occurring geogenic arsenic,fluoride and iodine in groundwater at Datong Basin,northern China[J].Journal of Hazardous Materials,2015,300:652-661.
[43] ZHANG Wei,TANG Xiangyu,XIAN Qingsong,et al.A field study of colloid transport in surface and subsurface flows[J].Journal of Hydrology,2016,542:101-114.
[44] SANTOSA I R,HUETTEL M.The driving forces of porewater and groundwater flow in permeable coastal sediments:a review[J].Estuarine Coastal & Shelf Science,2012,98(1):1-15.
[45] GROLIMUND D,BORKOVEC M.Colloid-facilitated transport of strongly sorbing contaminants in natural porous media:mathematical modeling and laboratory column experiments[J].Environmental Science & Technology,2005,39(17):6378-6386.
[46] FAN Chenxin,ZHANG Lu,QIN Boqiang,et al.Migration mechanism of biogenic elements and their quantification on the sediment-water interface of Lake Taihu:I.Spatial variation of the ammonium release rates and its source and sink fluxes[J].Journal of Lake Sciences,2004,16(1):10-20.
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