紫色土吸附Cu2+、Zn2+对水体中土壤颗粒凝聚沉降的影响
Effect of Cu2+and Zn2+ Adsorption on the Aggregation and Settling of Neutral Purple Soil Particles
投稿时间:2016-05-14  修订日期:2017-06-06
DOI:10.15928/j.1674-3075.2017.03.005
中文关键词:紫色土  Cu2+  Zn2+  土壤颗粒  沉降速率
英文关键词:neutral purple soil  Cu2+  Zn2+  soil particle  settling velocity  
基金项目:国家自然科学基金项目(41101223) ;重庆市自然科学基金项目(cstc2014jcyjA80031,cstc2015jcyjA80015);重庆市教委科技课题(KJ1501115)和重庆市大学生创新性训练计划(201410642005)
作者单位E-mail
丁武泉* 重庆文理学院环境材料与修复技术重庆市重点实验室重庆 402168西南大学土壤多尺度界面过程与调控重庆市重点实验室重庆 400716 wuquanding@sohu.com 
何家洪 重庆文理学院环境材料与修复技术重庆市重点实验室重庆 402168 12721947@qq.com 
王磊 重庆文理学院环境材料与修复技术重庆市重点实验室重庆 402168 1466141493@qq.com 
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中文摘要:
      研究中性紫色土表面吸附Cu2+、Zn2+后对其在水体中凝聚沉降的影响,为重金属离子释放对三峡库区水-土界面生态系统造成的风险提供数据参考。2014年10月,采集西南大学桑园的中性紫色土表层土壤,以Cu(NO3)2和Zn(NO3)2配置重金属离子,进行Cu2+和Zn2+对中性紫色土凝聚沉降实验、测定中性紫色土颗粒吸附Cu2+和Zn2+后zeta电位值。 (1) 中性紫色土吸附Cu2+、Zn2+后水体中土壤颗粒含量随时间不断减小,并且呈先快速后缓慢减小的规律,在不同浓度条件下土壤颗粒含量变化规律表现差异较大,其临界浓度分别为0.3~ 0.5和0.5~ 0.7 mmol/ L。(2) 水体中中性紫色土颗粒平均沉降速率均随Cu2+、Zn2+浓度升高而增大,分别从 1.01 cm/ min增加到2.92和2.58 cm/ min,表现为Cu2+ >Zn2+;过程分为3个阶段:缓慢增加,快速增加和基本不变,平均沉降速率随浓度变化临界范围分别为0.3~ 0.5和0.5~ 0.7 mmol/L。 (3) 水体中中性紫色土颗粒zeta 电位绝对值随Cu2+、Zn2+浓度升高而变小,同时表现为Ca2+ > Zn2+ > Cu2+,土壤颗粒吸附Ca2+、Cu2+和Zn2+后zeta电位绝对值随浓度变化临界浓度范围分别为0.8 、0.3~ 0.5和0.5~ 0.7 mmol/ L。重金属离子吸附在中性紫色土表面减小zeta电位值和静电斥力,加速土壤颗粒凝聚沉降过程。
英文摘要:
      Heavy metal pollution is a global environmental problem, resulting in serious ecological effects on water and soil. Heavy metal ions adsorbed on the soil surface alter the surface charge and affects aggregation and settling of soil particles. Purple soil is the primary soil type in the Three Gorges Reservoir area and Cu2+ and Zn2+ are common heavy metal pollutants, occurring at high concentrations in both soil and water. Here, we studied the effect of Cu2+and Zn2+ adsorption on the aggregation and settling of neutral purple soil particles to provide data for evaluating the ecological risk of heavy metal ion release to the water-soil interface. In October of 2014, surface soil (0-20 cm) was collected from the mulberry field of Southwest University, with a pH of 7.11, organic content of 1.23%, total surface change of 0.016 c mol/g and specific area of 4.8 x 104 m2/kg. Cu2+ and Zn2+ solutions of different concentrations (0, 0.1, 0.3, 0.5, 0.7, 0.9, 1.0 and 3.0 mmol /L) were prepared using Cu(NO3)2 and Zn(NO3)2. The aggregation and settling experiments were carried out in conical flasks and the absolute zeta potential of the soil particles in each group was determined after completing the experiments. Results show that: (1) Adsorption of Cu2+or Zn2+increased the settling rate , rapidly at first and then more slowly. The concentration of suspended soil particles varied significantly at different concentration Cu2+ and Zn2+ groups. The ranges of the critical concentrations of Cu2+and Zn2+ were, respectively, 0.3-0.5 mmol L-1and 0.5-0.7 mmol L-1, much lower than the critical concentration of Ca2+ (0.8 mmol L-1); (2) the average settling velocity of the neutral purple soil particles increased with Cu2+ or Zn2+ concentration within the critical concentration ranges and then increased, respectively, from (1.01+0.08 ) cm min-1 to (2.92+0.11) cm min-1 and (2.58+0.05) cm min-1. The change in settling velocity included three stages: an initial slow increase, a rapid increase, a plateau; (3) The absolute zeta potential of the neutral purple soil particles decreased with increasing Cu2+ and Zn2+ concentration and the zeta potential of soil particles in solutions of Ca2+, Zn2+ and Cu2+ ions followed the order Ca2+ > Zn2+ > Cu2+. The zeta potential also varied with the concentrations of Ca2+, Cu2+, Zn2+ within the range of critical concentrations, consistent with the changes in soil particle settling rate and average settling velocity. The results show that the key factor influencing aggregation and settling of soil particles is electrostatic repulsion.
丁武泉,何家洪,王磊.2017.紫色土吸附Cu2+、Zn2+对水体中土壤颗粒凝聚沉降的影响[J].水生态学杂志,38(3):32-37.
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