污染土壤中重金属的超声波强化EDTA洗脱及形态变化

以EDTA为洗脱剂,对重金属污染土壤进行超声波强化洗脱正交实验,并用Tessier连续提取法研究了洗脱前后Cd、Cu、Pb、Zn的形态变化.结果表明,在EDTA浓度20 mmol·L-1、固液比1∶20、超声波作用时间16 min、超声波功率54%、洗脱次数4次的条件下,对4种重金属洗脱率最大,分别为:Cd 83.6%、Cu 58.8%、Pb 98.0%、Zn 43.0%.在实验所设浓度范围内,随着EDTA浓度的升高,重金属洗脱率均有降低.形态分析结果显示,超声波强化EDTA洗脱能显著降低土壤重金属的残渣态含量.除土壤中Zn残渣态去除率只有5.7%以外,超声波强化EDTA洗脱对土壤中Cd、Cu、Pb的残渣态去除率都很高,分别为81.6%、62.3%、93.8%.     

贵阳市道路灰尘和土壤重金属来源识别比较

通过对89个城市土壤样和78个道路灰尘样中重金属含量的对比,利用多元统计方法识别研究区的元素来源.结果显示道路灰尘元素含量一般高于土壤.就均值而言,灰尘中Hg、Cd、Pb、Cu、Cr含量超过土壤中相应元素含量,灰尘中Zn含量与土壤中Zn含量相当,只有灰尘中As含量略低于土壤.灰尘中元素含量都高于中国和贵州表层土壤背景值,土壤中元素含量除Pb外都高于中国和贵州表层土壤背景值.Cd,Cr,Pb,Hg,Cu和Zn含量较高主要是受人为因素的影响.贵阳市道路灰尘和土壤中8种元素有着不同的来源.相关分析、主成分分析表明交通排放等人为因素是重金属主要来源,外来客土也是重金属重要来源;灰尘Pb主要来源于交通排放和钢铁厂;而土壤Cr具有复合污染的特征,主要来源于外来客土.     

浙中典型富硒土壤区土壤硒含量的影响因素探讨

通过对浙江省中部典型富硒土壤区的系统调查研究,总结了影响土壤硒含量的主要因素.结果表明,地质背景对土壤硒含量有控制作用,汤溪组、之江组和金华组分布区的土壤硒含量明显高于其他地质背景区.研究同时发现,土地利用方式对土壤硒的迁移富集有不可忽视的影响,旱地土壤比水田土壤更易富集硒元素.由于土壤有机质对硒的吸附与固定作用,致使其成为影响硒含量的重要因素之一.除此之外,研究认为土壤质地也是影响土壤硒含量的重要因素,土壤中黏粒含量越多,越黏重,硒含量往往较高.     

玉米秸秆生物炭对贵州黄壤持水能力的影响

生物炭具有丰富的微孔结构,能够影响土壤的持水性能,对植物生长和土壤中养分的保持有着重要意义。而土壤水分特征曲线又是表征土壤持水能力的一个重要指标。本文通过压力膜法测定添加不同比例生物炭的黄壤水分特征曲线,并结合van Genuchten模型对实测结果进行拟合,推导水动力学参数。结果表明,随着生物炭施入量的增加(0、5%、10%),土壤的田间持水量增加,凋萎含水量降低,土壤有效含水量增加。生物炭添加能够显著提高土壤的持水能力,增强水分的可利用性。同时,van Genuchten模型拟合结果同实测值高度相似,可以用作预测生物炭改良土壤的水动力学参数。     

城市土壤重金属污染及其生态环境效应

对城市土壤中重金属的来源、空间分布特征、化学形态、在不同介质间的迁移转化及其污染的生态环境效应等近年来的研究进展进行了回顾,指出今后的研究重点是建立城市土壤重金属污染风险评价和标准体系,并应对重金属在城市环境中的迁移转化机制及城市土壤质量演变与郊区之间的关系开展研究。     

Lead in Soil and Sediment in Iqaluit, Nunavut, Canada, and Links with Human Health

This study determined the spatial distribution of soiland of sediment-associated lead in Iqaluit, Nunavut.Samples were collected from the following areas:outside the built-up area of the town to reflectbackground concentrations; known or potential pointsources of lead, such as the Upper Base, the SylviaGrinnell Dump and the Metal Dump (North 40); andresidential and commercial areas of Iqaluit and Apex,a satellite community. In the laboratory, the <63 m sample fraction was analyzed for total lead andbioavailable lead, estimated by non-residual acidextractable lead content. The research findings revealthat elevated levels of bioavailable lead are presentin the study area. Total lead concentrations generallydo not exceed environmental guidelines. However, leadconcentrations in the Sylvia Grinnell Dump, and Apexand Iqaluit grid areas exceed health-based guidelines.The research concludes that there is not a serioushealth hazard posed by lead levels in the soil andsediment in the study area. However, severalenvironmental (elevated lead levels, bioavailableforms of lead and bare soil surfaces) and behaviouralfactors (vigorous and unsupervised play outside) maycreate a risk of lead exposure.     

黄土丘陵区生物结皮对土壤物理属性的影响

生物结皮在干旱、半干旱地区广泛发育。迄今,有关生物结皮发育过程中土壤物理属性的响应仍不明确。论文采用野外调查与室内分析相结合的方法,定量研究不同生物量生物结皮对土壤物理属性的影响。结果表明:①生物结皮的发育能够细化土壤,当生物结皮由初期藻结皮演替至60%~80%苔藓结皮时(5等级),生物结皮层粗砂粒含量降低了86%;②随着生物结皮生物量的增加,生物结皮层土壤容重和硬度较初期分别降低了15%和68%,田间持水量和孔隙度分别增加了36%和14%;生物结皮层粘结力是下层土壤的6~7倍;③生物结皮的发育对土壤物理属性的影响与生物量有关,当苔藓生物量达2.91±0.12 g/dm²时,其土壤物理属性基本稳定。研究结果为揭示生物结皮抗侵蚀机理提供了科学参考。     

土壤及土壤矿物对类胡敏酸的吸附解吸及其影响因素研究

应用平衡吸附法,研究了不同pH值、离子强度、类胡敏酸浓度和接触时间条件下,黑土、白浆土及蒙脱石对类胡敏酸(HLA)的吸附作用.结果表明:随着HLA浓度的增加,土壤及蒙脱石对HLA的吸附量增加.黑土、白浆土及蒙脱石对HLA的吸附等温线均为L型,其吸附不可逆性表现为白浆土＞蒙脱石＞黑土.通过Langmiur方程计算,蒙脱石、白浆土对HLA达到吸附平衡时的最大吸附量分别为764.7、790.3 mg·g-1,而黑土为35.27 mg·g-1.Freundlich方程可以很好地描述白浆土、蒙脱石对HLA的吸附和解吸等温线,而Temkin方程可以很好地描述黑土对HLA的吸附和解吸等温线.同时,3种材料的吸附自由能△G°＜0,吸附热Qm ＞0,表明其对HLA的吸附是自发的、放热的过程.随着pH的升高,黑土、白浆土及蒙脱石对HLA的吸附量减少;随离子强度的增加,黑土、白浆土及蒙脱石对HLA的吸附量增大.黑土、白浆土及蒙脱石对HLA的吸附动力学过程划分为快反应和慢反应阶段,其中,蒙脱石、白浆土对HLA的吸附动力学过程用一级动力学方程拟合的效果最好,而对黑土而言,用Elovich方程描述更合适.     

Effects of the new nitrification inhibitor 3,4-dimethylpyrazole phosphate (DMPP) on nitrate and potassium leaching in two soils

In this study, soil column was used to study the new nitrification inhibitor 3,4-dimethylpyrazole phosphate (DMPP) on nitrate (NO3--N) and potassium (K) leaching in the sandy loam soil and clay loam soil. The results showed that DMPP with ammonium sulphate nitrate (ASN) ((NH4)2SO4 and NH4NO3) or urea could reduce NO3--N leaching significantly, whereas ammonium (NH4 -N) leaching increased slightly. In case of total N (NO3--N NH4 -N), losses by leaching during the experimental period (40 d) were 37.93 mg (urea), 31.61 mg (urea DMPP), 108.10 mg (ASN), 60.70 mg (ASN DMPP) in the sandy loam soil, and 30.54 mg (urea), 21.05 mg (urea DMPP), 37.86 mg (ASN), 31. 09 mg (ASN DMPP) in the clay loam soil, respectively. DMPP-amended soil led to the maintenance of relatively high levels of NH4 -N and low levels of NO3--N in soil, and nitrification was slower. DMPP supplementation also resulted in potassium leached less, but the difference was not significant except the treatment ASN and ASN DMPP in the sandy loam soil. Above results indicate that DMPP is a good nitrification inhibitor, the efficiency of DMPP seems better in the sandy loam soil than in the clay loam soil and lasts longer.     

Responses of chlorophyll fluorescence and nitrogen level of Leymus chinensis seedling to changes of soil moisture and temperature

Controlled experiment of Leymus chinensis seedlings grown in the environmental growth chambers at 3 soil moisture levels and 3 temperature levels was conducted in order to improve the understanding how leaf photosynthetic parameters will respond to climatic change. The results indicated that soil drought and high temperature decreased the photochemical efficiency of photosystem ( Fw/Fm ), the overall photochemical quantum yield of PSIl(yield), the coefficient of photochemical fluorescence quenching(qp), but increased the coefficient of non-photochemical fluorescence quenching( q, ). Severe soil drought would decrease Fv/Fm and yield by 3.12% and 37.04% under 26% condition, respectively, and 6.60% and 73.33% under 32% condition, respectively,suggesting that higher temperature may enhance the negative effects of soil drought. All the soil drought treatments resulted in the decline in leaf nitrogen content. There was no significant effect of temperature on leaf nitrogen level,but higher temperature significantly reduced the root nitrogen content and the ratio of root nitrogen to leaf nitrogen,indicating the different strategies of adaptation to soil drought and temperature. It was also implied that higher temperature would enhance the effect of soil drought on leaf photosynthetic capacity, decrease the adaptability of Leymus chinensis to drought.