农业工程学报
農業工程學報
농업공정학보
2015年
5期
132-138
,共7页
雷文娟%唐翔宇%关卓%周向阳%王秉玺%张维
雷文娟%唐翔宇%關卓%週嚮暘%王秉璽%張維
뢰문연%당상우%관탁%주향양%왕병새%장유
污染%径流%吸附%3,5,6-TCP%毒死蜱%紫色土%CDE模型%耕作类型
汙染%徑流%吸附%3,5,6-TCP%毒死蜱%紫色土%CDE模型%耕作類型
오염%경류%흡부%3,5,6-TCP%독사비%자색토%CDE모형%경작류형
pollution%runoff%adsorption%3,5,6-TCP%Chlorpyifos%Purple soil%CDE model%Tillage types
3,5,6-三氯-2-吡啶醇(TCP)的化学结构稳定、水溶性高、运移能力强,对水体具有潜在的污染风险。在有机质含量低、大孔隙度高、导水性好的紫色土地区,风险更加显著。为研究TCP在紫色中的迁移规律,该研究依据紫色土的典型耕作类型,在中国科学院盐亭国家紫色土农业生态试验站采集3组土样(小麦-玉米轮作的坡地、水稻-油菜轮作的水旱农田和萝卜-白菜套种的菜地),通过批量平衡法研究紫色土对TCP的吸附特征,并采用稳定流场饱和均质土柱的易混合置换试验研究TCP的动态迁移过程,最后对其迁移动态进行模拟。结果表明:紫色土对TCP的吸附特征呈线性,在坡地、水旱农田和菜地中的吸附系数分别为1.94、1.22和1.02 L/kg,且黏土含量和矿物组成是主要影响因子;TCP的出流平衡浓度分别为初始浓度的77%(坡地)、84%(水旱农田)和92%(菜地),相应的平衡时刻分别为2.88PV、4PV和6.5PV,表明TCP对环境的污染风险较高;用非平衡两点对流弥散模型模拟TCP在3种耕作条件下迁移,表明TCP以瞬时吸附为主,其水动力弥散系数和分形系数在坡地、水旱农田和菜地中依次减小,但一阶动力学常数依次增大。研究结果为探索TCP在紫色土壤中的迁移机制和预测防止TCP对环境的污染提供了参考依据。
3,5,6-三氯-2-吡啶醇(TCP)的化學結構穩定、水溶性高、運移能力彊,對水體具有潛在的汙染風險。在有機質含量低、大孔隙度高、導水性好的紫色土地區,風險更加顯著。為研究TCP在紫色中的遷移規律,該研究依據紫色土的典型耕作類型,在中國科學院鹽亭國傢紫色土農業生態試驗站採集3組土樣(小麥-玉米輪作的坡地、水稻-油菜輪作的水旱農田和蘿蔔-白菜套種的菜地),通過批量平衡法研究紫色土對TCP的吸附特徵,併採用穩定流場飽和均質土柱的易混閤置換試驗研究TCP的動態遷移過程,最後對其遷移動態進行模擬。結果錶明:紫色土對TCP的吸附特徵呈線性,在坡地、水旱農田和菜地中的吸附繫數分彆為1.94、1.22和1.02 L/kg,且黏土含量和礦物組成是主要影響因子;TCP的齣流平衡濃度分彆為初始濃度的77%(坡地)、84%(水旱農田)和92%(菜地),相應的平衡時刻分彆為2.88PV、4PV和6.5PV,錶明TCP對環境的汙染風險較高;用非平衡兩點對流瀰散模型模擬TCP在3種耕作條件下遷移,錶明TCP以瞬時吸附為主,其水動力瀰散繫數和分形繫數在坡地、水旱農田和菜地中依次減小,但一階動力學常數依次增大。研究結果為探索TCP在紫色土壤中的遷移機製和預測防止TCP對環境的汙染提供瞭參攷依據。
3,5,6-삼록-2-필정순(TCP)적화학결구은정、수용성고、운이능력강,대수체구유잠재적오염풍험。재유궤질함량저、대공극도고、도수성호적자색토지구,풍험경가현저。위연구TCP재자색중적천이규률,해연구의거자색토적전형경작류형,재중국과학원염정국가자색토농업생태시험참채집3조토양(소맥-옥미륜작적파지、수도-유채륜작적수한농전화라복-백채투충적채지),통과비량평형법연구자색토대TCP적흡부특정,병채용은정류장포화균질토주적역혼합치환시험연구TCP적동태천이과정,최후대기천이동태진행모의。결과표명:자색토대TCP적흡부특정정선성,재파지、수한농전화채지중적흡부계수분별위1.94、1.22화1.02 L/kg,차점토함량화광물조성시주요영향인자;TCP적출류평형농도분별위초시농도적77%(파지)、84%(수한농전)화92%(채지),상응적평형시각분별위2.88PV、4PV화6.5PV,표명TCP대배경적오염풍험교고;용비평형량점대류미산모형모의TCP재3충경작조건하천이,표명TCP이순시흡부위주,기수동력미산계수화분형계수재파지、수한농전화채지중의차감소,단일계동역학상수의차증대。연구결과위탐색TCP재자색토양중적천이궤제화예측방지TCP대배경적오염제공료삼고의거。
3,5,6-trichloro-2-pyridinol (TCP), the main degradation product of pesticide chlorpyrifos and herbicide triclopyr, exhibits strong anti-degradation ability, high water solubility and high migration capability, which would easily lead to soil and water pollution. This situation would be worse in the purple soil distribution areas, most in the upstream regions of Yangtze River, due to soils with low organic matter content, large pores with high water conductivity and erosion. In this study, three typical farmland soil samples were collected based on major land use of purple soil from Chinese Academy of Agricultural Agro Ecological Experimental Station (Yanting), including a sloping field sample located at higher relative elevation, a paddy field sample at lower relative elevation and a vegetable field sample close to the residential areas, corresponding to the crop rotation of wheat-corn, rice-rape and radish-cabbage, respectively. Physical properties of these soil samples were measured, including particle-size fraction, organic matter content, bulk density, pH value and content of clay minerals (montmorillonite and kaolinite). Then, the batch equilibrium method was used to determine the liquid - solid partition coefficient of the TCP to reveal the absorbing characteristics of these purple soil samples to TCP; meanwhile, miscible displacement experiment was carried out under steady-state flow condition (12 mL/h) with Br-as a conservative tracer (50 mg/L), from which dispersion coefficient for TCP transport could be estimated by inverse simulation. Finally, the appropriate models were selected to simulate the physical and chemical processes of TCP in purple soil columns. The results were as follows: 1) The absorbing characteristics of purple soil to TCP were well described by the linear form of Freundlich Model, and the adsorption coefficients of sloping field, paddy field and vegetable field were 1.94, 1.22 and 1.02 L/kg, respectively. The content of clay and its components (montmorillonite and kaolinite) were the main factors affecting the adsorption coefficients; 2) The equilibrium outflow concentration of TCP in the outflow was 77%, 84% and 92% (relative concentration to the TCP outflow) respectively and the equilibrium time was at 2.88 PV, 4 PV and 6.5 PV, suggesting high pollution risk to deep soil layer, surface water and groundwater. Especially in the slope field, TCP displayed more easily and faster to enter the groundwater through infiltration and rivers through the surface runoff and lateral flow at the slope. 3) The two sites non-equilibrium convection-diffusion model could well simulate the transportation of TCP through purple soil columns, with a determination coefficient larger than 0.90 and the mean square errors (MSE) ranging from 0.009 to 0.021. These hydrodynamic and absorbing parameters from the experiment or reverse simulation revealed the reasons why TCP transportation was different among the three farmland purple soils: in the transient-absorption-dominated uniform soil environment, the main factor affecting dispersion coefficient was the flow velocity, which was mainly controlled by soil porosity or bulk density under the condition of stead flow without pressure; and dispersion coefficient and first-order kinetic rate constant showed an increase trend from vegetable field to paddy field, and then sloping field, while fractal coefficient displayed a decrease trend. These results are important to disclose TCP transfer mechanism in purple soil, and can also provide valuble information for preventing pollution caused by the pesticide and herbicide, especially their degradation productions, to the soil and water environment in the upstream regions of Yangtze River.
