广东省主要蔬菜产地土壤中重金属含量调查与评价

调查了广东省20个市(县)52个主要蔬菜产地土壤重金属含量,并以<土壤环境质量标准>(GB 15618-1995)二级标准为评价标准,采用单项污染指数法和综合污染指数法对其进行评价.结果表明,156个蔬菜产地土壤样品中Cd、Hg、As和Cr的超标率分别为9.62%、3.85%、0.64%和0.64%,Pb未出现超标;有8个蔬菜产地土壤重金属处于轻污染,13个蔬菜产地土壤重金属处于警戒限,其余蔬菜产地土壤重金属均在安全范围内.蔬菜产地土壤Cd污染最为普遍和严重,其次是Hg和As,且Cd的变异系数为103.67%,预示蔬菜产地土壤可能受到Cd的点源污染.珠江三角洲地区蔬菜产地土壤重金属含量普遍高于其他地区,粤西和粤北地区个别蔬菜产地土壤重金属超标.     

农田蔬菜中重金属污染和铅稳定同位素特征分析

采集南京市栖霞山铅锌矿附近农田中6种蔬菜和相应的根际土壤,测定了蔬菜(根系和茎叶)和根际土壤样品铅、镉、铜和锌含量和铅稳定同位素比率.结果表明,土壤受到铅、镉和锌污染,其中镉是最重要污染物;蔬菜根系和茎叶铅、镉、铜和锌含量具有明显的种属特异性;与<食品中污染物限量>(GB 2762-2005)、<食品中铜限量卫生标准>(GB 15199-1994)和<食品中锌限量卫生标准>(GB 13106-1991)中阈值相比.蔬菜中铅、镉和锌含量超标严重.铅稳定同位素比率表明.蔬菜的铅稳定同位素比率与土壤铅稳定同位索比率明显不同.因而土壤不是蔬菜富集铅的全部来源,大气可能是其重要来源之一.     

贵州水城典型铅锌矿区土壤和蔬菜中重金属累积特征及风险评价

以贵州水城茨冲永昌、仁活洞杉树林和凉山玉兰3个典型铅锌矿区为研究对象,采集了白菜、辣椒、玉米、马铃薯、黄豆、四季豆6种蔬菜样品及其对应的根际土壤样品。分析了蔬菜与土壤中Pb、Zn、Ni、Cd、Cr、As、Hg、Cu 8种重金属的含量及蔬菜对根际土壤重金属的累积特征,同时采用内梅罗综合污染指数法、目标危险系数法及综合质量影响指数法对土壤及蔬菜重金属污染进行评价。结果表明:根际土壤中Pb、Zn、Ni、Cd、Cr、As、Hg、Cu总平均值分别为1 198.2、2 378.8、53.0、7.0、122.6、56.9、0.37、107.5mg/kg,分别是贵州土壤环境背景值的34.0、23.9、1.4、10.0、1.3、2.8、3.4、3.4倍;不同蔬菜对土壤中不同重金属的富集能力有较大差异;内梅罗综合污染指数表明,研究区土壤中8种重金属均属于重污染;蔬菜中重金属对当地儿童、青壮年、中老年的总健康风险指数均大于1,存在健康风险;综合质量影响指数也表明,研究区的综合质量属于重度污染。     

钢丝绳产业区废水重金属对土壤与蔬菜的影响及生态风险评价

选取钢丝绳产业区某较发达的一乡镇为研究区域,对其周边土壤及蔬菜的污染状况进行调查和实验研究,结果表明：（1）钢丝绳产业区废水重金属对附近土壤并未产生较大污染,蔬菜重金属元素锌的安全率为100％,铅仅为55％。（2）钢丝绳产业区叶类蔬菜中铅的含量最高,豆类蔬菜中却是锌的含量最高,根茎类蔬菜中铅和锌的含量均较低。     

宝应县土壤重金属的污染调查

以宝应县农田土壤重金属调查为依据，采用污染指数法对土壤质量进行评价，分析土壤重金属污染原因，提出防治措施。     

合肥市菜园蔬菜和土壤的铅污染调查

本文分析了合肥市郊菜园蔬菜和土壤的铅含量,蔬菜含铅0.13～2.83ppm,土壤含铅20～42.5ppm,可溶性铅为0.2～13.2ppm。讨论了不同蔬菜、蔬菜不同部位之间含铅量的差别,以及地点、距离、pH、环境条件等因素对土壤和蔬菜铅污染的影响,提出减少汽车废气对市郊菜园蔬菜和土壤铅污染的一些措施。     

土壤中重金属污染的研究进展

介绍了土壤重金属的污染及其特点，重金属对环境危害和在土壤中的化学行为，最后论述了土壤重金属元素的背景值。     

绿色食品蔬菜生产中若干污染物的容许限量

讨论了绿色食品蔬菜中镉和灌溉水中氯化物的限量水平。建议蔬菜中镉的浓度应控制在０．０５ｍｇ／ｋｇ下,滨海地区灌溉水中Ｃｌ＾－含量可不作为限制因素。     

无公害蔬菜生产基地环境质量研究

无公害蔬菜的产地,必须达到一定的环境质量标准,故生产基地环境质量研究是生产无公害蔬菜的第一关。主要环境要素有：土壤、水质、大气环境,同时检测基地现产蔬菜中农药残留量。     

大田条件下施加组配改良剂对蔬菜吸收重金属的影响

通过向湘南某矿区周边重金属污染的农田施加不同添加量(0、2、4和8 g/kg)的组配改良剂HS(海泡石+石灰石),分析农田土壤理化性质变化和土壤重金属及其交换态含量的影响、空心菜和辣椒可食部位和根部位重金属含量的影响。结果表明,施用2~8 g/kg组配改良剂HS能使2种蔬菜土壤pH值和CEC含量显著增加,使交换态重金属含量大幅降低,且不同程度地降低了空心菜和辣椒可食部位及根部位的重金属含量。与对照相比,空心菜和辣椒可食部位重金属Pb、Cd、Cu、Zn的降幅分别为:21.1%~47.5%、6.5%~31.0%、57.7%~80.0%、65.3%~92.0%和27.3%~74.5%、29.8%~62.0%、55.4%~76%、37.8%~77.1%;根部位的重金属含量也有明显降低。当添加量为8 g/kg时,2种蔬菜可食部位和根部位重金属含量降低幅度最大。由此可知,组配改良剂HS的施用对2种蔬菜吸收土壤重金属起到有效的抑制作用。     

生物吸附重金属的研究进展

从生物吸附的概念、吸附重金属的机理、吸附剂的种类以及生物细胞的固定化、生物吸附工艺过程等方面进行了综述，同时阐述了生物吸附重金属的技术研究进展和应用前景展望。     

城市污水处理厂的污泥农用对土壤的重金属影响

污泥农用是城市污水处理厂污泥资源化利用的有效途径,但污泥中的重金属元素含量高,可能成为环境中的一种安全隐患。重金属对环境的危害不仅与其总量有关,更大程度上由其形态分布所决定。实验研究了污泥农用所引入的重金属对土壤重金属总量及其形态的影响,研究结果表明,污泥农用虽然明显增加了土壤中的重金属总量,但重金属在土壤中的活性却受到了抑制,从而降低了重金属通过食物链危害人类健康的风险。     

土壤重金属污染的植物修复研究进展

详细阐述了植物修复的生理学、分子生物学机制，包括超积累植物对根际土壤中重金属的活化，超量积累植物对土壤重金属吸收及其解毒机理，并就该领域今后的研究方向和存在的问题作了探讨。     

重金属离子Cd^2＋、Pb^2＋污染对土壤酶活性的影响

通过对土壤中比较重要的两种酶（过氧化氢酶、脲酶）活性的测定,研究了重金属离子（Cd^2＋、Pb^2＋）单因素污染、复合污染对两种酶活性的影响,进而找出重金属污染程度与土壤酶活性的关系,为建立土壤中的酶活性可以表征重金属污染程度的生化指标平台提供试验依据。结果表明,在Cd^2＋、Pb^2＋单因素污染影响中,在一定浓度下的重金属离子对土壤酶活性会有激活效应,但大多表现为抑制效应;Cd^2＋、Pb^2＋复合污染对两种土壤酶活性的影响存在着明显差异,其复合污染对脲酶表现出协同抑制负效应的特征;对过氧化氢酶表现出一定的屏蔽作用。通过重金属离子形态对土壤酶有效性影响的研究,脲酶活性可以作为土壤重金属离子（Cd^2＋、Pb^2＋）单因素和复合污染程度的主要生化指标。     

Effects of Soil Amendments at a Heavy Loading Rate Associated with Cover Crops as Green Manures on the Leaching of Nutrients and Heavy Metals from a Calcareous Soil

The potential risk of groundwater contamination by the excessive leaching of N, P and heavy metals from soils amended at heavy loading rates of biosolids, coal ash, N‐viro soil (1:1 mixture of coal ash and biosolids), yard waste compost and co‐compost (3:7 mixture of biosolids to yard wastes), and by soil incorporation of green manures of sunn hemp (Crotalaria juncea) and sorghum sudangrass (Sorghum bicolor × S. bicolor var. sudanense) was studied by collecting and analyzing leachates from pots of Krome very gravelly loam soil subjected to these treatments. The control consisted of Krome soil without any amendment. The loading rate was 205 g pot^? 1 for each amendment (equivalent to 50 t ha^? 1 of the dry weight), and the amounts of the cover crops incorporated into the soil in the pot were those that had been grown in it. A subtropical vegetable crop, okra (Abelmoschus esculentus L.), was grown after the soil amendments or cover crops had been incorporated into the soil. The results showed that the concentration of NO₃‐N in leachate from biosolids was significantly higher than in leachate from other treatments. The levels of heavy metals found in the leachates from all amended soils were so low, as to suggest these amendments may be used without risk of leaching dangerous amounts of these toxic elements. Nevertheless the level of heavy metals in leachate from coal ash amended soil was substantially greater than in leachates from the other treatments. The leguminous cover crop, sunn hemp, returned into the soil, increased the leachate NO₃‐N and inorganic P concentration significantly compared with the non‐legume, sorghum sudangrass. The results suggest that at heavy loading rates of soil amendments, leaching of NO₃ ^? could be a significant concern by application of biosolids. Leaching of inorganic P can be increased significantly by both co‐compost and biosolids, but decreased by coal ash and N‐viro soil by virtue of improved adsorption. The leguminous cover crop, sunn hemp, when incorporated into the soil, can cause the concentration of NO₃‐N to increase by about 7 fold, and that of inorganic P by about 23% over the non‐legume. Regarding the metals, biosolids, N‐viro soil and coal ash significantly increased Ca and Mg concentrations in leachates. Copper concentration in leachate was increased by application of biosolids, while Fe concentration in leachates was increased by biosolids, coal ash and co‐compost. The concentrations of Zn, Mo and Co in leachate were increased by application of coal ash. The concentrations of heavy metals in leachates were very low and unlikely to be harmful, although they were increased significantly by coal ash application.     

Geostatistical Assessment of the Impact of World War I on the Spatial Occurrence of Soil Heavy Metals

Previous research showed a regional Cu enrichment of 6 mg kg⁻¹ in the top soil of the Ypres war zone (Belgium), caused by corrosion of WWI shell fragments. Further research was required since in addition to Cu, also As, Pb, and Zn were used during the manufacturing of ammunition. Therefore, an additional data collection was conducted in which the initial Cu data set was tripled to 731 data points and extended to eight heavy metals (As, Cd, Cr, Cu, Hg, Ni, Pb, and Zn) which permitted (1) to evaluate the environmental impact of the heavy metals at a regional scale and (2) to assess their regional spatial occurrence by performing an optimized geostatistical modeling. The results showed no pollution at a regional scale, but sometimes locally concentrations exceeded the soil sanitation threshold, especially for Cu, Pb, and Zn. The spatial patterns of Ni and Cr were related to variations in soil texture whereas the occurrences of Cu and Pb were clearly linked to WWI activities. This difference in spatial behavior was confirmed by an analysis of coregionalization.     

我国底泥重金属污染防治

重金属在大气、水体、土壤、生物体中广泛分布，而底泥往往是重金属的储存库和最后的归宿。当环境变化时，底泥中的重金属形态将发生转化并释放造成污染。重金属不能被生物降解，但具有生物累积特性，可以直接威胁高等生物包括人类，因此，底泥重金属污染问题日益受到人们的重视。作者综述了我国底泥重金属的污染状况、存在形态、释放规律和治理措施，并提出了需要深入研究的问题。     

Contents and Leachability of Heavy Metals (Pb,Cu, Sb,Zn, As) in Soil at the Pantex Firing Range,Amarillo, Texas

ABSTRACT

Pantex firing range soil samples were analyzed for Pb, Cu, Sb, Zn, and As. One hundred ninety-seven samples were collected from the firing range and vicinity area. There was a lack of knowledge about the distribution of Pb in the firing range, so a random sampling with proportional allocation was chosen. Concentration levels of Pb and Cu in the firing range were found to be in the range of 11-4675 and 13-359 mg/kg, respectively. Concentration levels of Sb were found to be in the range of 1-517 mg/kg. However, the Zn and As concentration levels were close to average soil background levels. The Sn concentration level was expected to be higher in the Pantex firing range soil samples. However, it was found to be below the neutron activation analysis (NAA) detection limit of 75 mg/kg.

Enrichment factor analysis showed that Pb and Sb were highly enriched in the firing range with average magnitudes of 55 and 90, respectively. Cu was enriched ~6 times more than the usual soil concentration levels. Tox-icity characteristic leaching procedure (TCLP) was carried out on size-fractionated homogeneous soil samples. The concentration levels of Pb in leachates were found to be ~12 times higher than the U.S. Environmental Protection Agency (EPA) regulatory concentration level of 5 mg/L. Sequential extraction (SE) was also performed to characterize Pb and other trace elements into five different fractions. The highest Pb fraction was found with organic matter in the soil.