石灰用量对污染红壤和黄泥土中有效态铜锌含量的影响

采用外源加入重金属铜锌硝酸盐的方法,制成铜、锌单一及复合污染的三级污染红壤和黄泥土（Cu 200mg/kg、Zn 400 mg/kg）,稳定一个月,施入低（0.50 g/kg）、中（1.50 g/kg）和高（2.50 g/kg）3种不同用量的石灰,稳定两个月后测定土壤有效态铜、锌含量和pH值,以阐明石灰用量对不同污染土壤中重金属有效态含量的影响。结果表明,随石灰用量的增加,复合污染红壤中有效态铜含量较对照依次降低31%、76%和87%;而石灰用量对黄泥土中有效态铜影响的差异不显著;两种土壤中有效态锌含量均随石灰用量的增加而显著减少;复合污染较单一污染相比,有效态铜及有效态锌的含量差异不显著。在复合污染下,低、中量石灰使黄泥土中有效态铜含量较红壤减少89%和63%,有效态锌减少27%和65%。但加入高量石灰,两种土壤差异不显著。石灰能够降低单一与复合污染铜、锌有效态的含量,但其效果因土壤类型而异,在红壤上选择施用高量石灰而在黄泥土上则适宜施用低中量石灰,以取得最佳的修复效果和效益。     

三峡库区柑橘园土壤重金属行为特征研究

试验研究三峡库区奉节县、忠县、长寿湖和江津市柑橘园土壤重金属行为特征结果表明,0~30cm土层土壤全Cd、有效镉含量显著高于30~60cm土层,说明三峡库区柑橘园土壤已受到Cd污染;三峡库区柑橘园土壤重金属源于成土母岩,柑橘园黄壤全Cu、全Cr、全Zn和全As含量显著高于紫色土,而有效锌、有效镉、有效铜和有效铅含量显著低于紫色土。柑橘园紫色土中有效镉占全量百分比达30.39%,黄壤中有效镉占全量百分比仅为2.30%。     

生物炭/石灰混施对重金属复合污染土壤的稳定化效应

采用室内模拟实验,以南方砷镉铅复合污染的酸性红壤为对象,利用化学钝化原理,探讨钝化材料对重金属稳定化的技术效果及应用配方,以期为砷镉铅复合污染红壤修复与安全利用提供依据。具体做法为：选择生物炭（BC）和石灰（SH）为钝化材料,以土壤重量的1%、4%为材料添加量,单一或混合施用于砷镉铅复合污染土壤,并于恒温（25℃）条件下培养60d,在实验进行至第1天、第30天、第60天时取样,测定红壤酸碱度（pH）和水溶态（Water soluble）有效砷（As）、镉（Cd）、铅（Pb）即WSAs、WSCd、WSPb含量,以及土壤重金属As、Cd、Pb结合态含量与占比的变化,明确生物炭石灰单/混施对重金属的稳定化效应。结果表明：生物炭/石灰无论单施或混施均能不同程度地降低土壤中水溶态WSCd和WSPb含量,钝化效率分别为33.51%～78.89%和9.05%～96.24%。而材料单施（1BC、4SH）和两者混施高用量（4BC4SH）处理,均能大幅降低土壤中有效As含量,钝化效率为10.25%～55.27%,其中以两者混施高用量（4BC4SH）处理对土壤重金属As、Cd、Pb协同钝化的效果最佳,当培养实验进行至第60天时,钝化效率依次达55.27%、76.39%和96.24%。培养后土壤中As形态由易被植物吸收的非专性吸附态、专性吸附态转化为稳定的残渣态,土壤中Cd和Pb则由活性最强的酸可提取态转化为残渣态,土壤中As、Cd、Pb的稳定化效应明显,迁移系数下降;此外,生物炭/石灰的单施及混合施用,均可导致土壤酸碱度（pH）显著提升（P<0.05）,有利于南方酸化土壤的改良。总体而言,本研究中生物炭/石灰两者混施高用量水平下（4BC4SH）土壤重金属的钝化效果最优,可实现对As、Cd和Pb复合污染红壤的稳定化修复。     

磷灰石等改良剂对重金属铜镉污染土壤的田间修复研究

通过田间小区试验,研究了磷灰石、石灰、木炭、猪粪、铁粉5种改良剂对Cu、Cd复合污染土壤的改良效果。结果表明,石灰、磷灰石、木炭、猪粪降低了土壤溶液中重金属Cu、Cd的含量,提高了土壤溶液的pH,但改良效果随着时间的推移不断降低。磷灰石、石灰、木炭的加入显著降低了有效态Cu含量,但对有效态Cd含量影响较小。与猪粪相比,磷灰石、石灰、木炭显著增加了黑麦草生物量,提高了对重金属Cu、Cd的吸收能力,对该污染土壤的修复具有实践应用价值。     

四种改良剂对铜和镉复合污染土壤的田间原位修复研究

研究了石灰、磷灰石、蒙脱石和凹凸棒石对冶炼厂周边Cu、Cd污染土壤的原位修复效果。以黑麦草(Lolium perenne L.)作为田间修复植物,采用植物重金属吸收性、土壤重金属化学提取性及土壤溶液重金属浓度变化等作指标来评价修复效果,并研究了黑麦草对Cu、Cd的吸收与土壤、土壤溶液中Cu、Cd含量的相关性。结果表明,石灰高添加剂量(石灰占污染土壤耕作层质量的0.4%)处理黑麦草对重金属的富集效果最好,显著降低了重金属毒性,促进了黑麦草的生长及其对重金属的富集;石灰和磷灰石各添加剂量均显著降低了污染土壤交换态Cu含量;石灰、磷灰石和蒙脱石各添加剂量均显著提高了土壤溶液pH并显著降低了其Cu、Cd浓度。黑麦草地上部、根中Cu浓度与土壤交换态Cu及土壤溶液Cu浓度呈显著或极显著正相关关系。     

辽宁省设施土壤重金属Cd、Ni、As有效态含量及其影响因素的研究

为探讨不同种植年限、不同土层土壤中重金属有效态含量,采集136 个辽宁省设施土壤及其相邻露地样品,分层测定了0~20 cm和20~40 cm土壤中有效态As、Cd和Ni的含量,并分析了影响其含量的因素。结果表明,设施土壤重金属有效态含量与其相邻露地土壤相比,各土层重金属有效态的含量均有所增加,且种植年限与3种重金属有效态的平均增量呈正相关。设施土壤pH值与有效态As呈正相关,与有效态Cd和Ni呈极显著负相关;有机质与有效态As和Cd均呈极显著的正相关,而与有效态Ni仅在20~40 cm土层呈显著正相关。     

石灰与生物炭配施对不同浓度镉污染土壤修复

通过室内培养试验,研究生物炭与石灰不同用量配施对镉污染土壤pH和镉赋存形态的影响。结果表明,生物炭与石灰配施能够明显提高污染土壤pH,且随着施入量的增加pH提升效果显著。随着石灰和生物炭配施用量的增加,土壤交换态镉降低比例逐渐增大。培养60天后,镉污染浓度为5mg/kg的土壤交换态镉含量同对照处理相比依次减少36.80%,49.12%和57.38%;而土壤镉污染浓度为20mg/kg的土壤交换态镉含量较对照相比分别降低29.27%,31.68%和39.03%。2个浓度中土壤碳酸盐结合态镉、铁锰氧化物结合态镉和有机结合态镉均有所增加,残渣态镉虽有所增加,但在不同浓度之间存在差异。总体来看,本试验用量条件下,石灰和生物炭配施对污染浓度为5mg/kg的土壤镉钝化效果优于污染浓度为20mg/kg的土壤。     

石灰在酸性稻田的施用效果

在土壤呈酸性且重金属铜、镉含量相对较高的稻田开展施用石灰效果试验。试验显示,施用石灰可提升土壤pH值,平均750 kg/hm~2石灰提升土壤pH值0.179;施用石灰可促进土壤有机质分解,增加土壤氮和磷的有效性,也会影响土壤铜、镉全量变化。试验初步表明,处理C(石灰用量750 kg/hm~2)的稻米对铜、镉富集能力较强。增施石灰可减少土壤铜、镉向稻米转移富集。水稻对镉的富集能力高于对铜的富集能力。试验表明,施用石灰可增加水稻有效穗数和千粒重,增产效果显著。以石灰用量750 kg/hm~2的水稻产量最高,效益最好,比CK增产干谷619.7 kg/hm~2,每千克石灰增产稻谷0.83 kg,净收入1 068.7元/hm~2,产投比为2.66。科学施用石灰可促进水稻增产和减轻稻米对铜、镉富集。     

生物炭复配矿物质钝化修复重金属复合污染土壤的研究

选取稻壳生物炭、木屑生物炭、羟基磷灰石及蒙脱石作为钝化材料,按钝化剂5:土壤100的重量比添加到重金属复合污染土壤中,通过测定土壤重金属形态变化,研究了钝化材料修复重金属复合污染土壤的效果及其机理。结果表明:生物炭和矿物质均能有效固定土壤中重金属,其中羟基磷灰石的钝化效果最好,对土壤镉、铜和铅的固定化率分别为76.24%、74.26%和98.13%。蒙脱石的钝化效果最差。添加钝化剂后土壤重金属中的酸可提取态和可还原态向着更加稳定的可氧化态和残渣态转化,土壤重金属活性态比例下降。生物炭复配矿物质处理对土壤重金属的钝化效果介于单一生物炭处理和单一矿物质处理之间。此外,生物炭及矿物质均能有效地提高土壤pH,pH可能是影响土壤修复效果的关键因素。     

骨炭+沸石对重金属污染土壤的修复效果及评价

采用盆栽试验,研究了铜铅镉复合污染土壤添加骨炭和沸石前后对土壤pH值、土壤中重金属有效态含量、蕹菜生长、重金属吸收量的影响。结果表明,土壤污染后pH值显著降低,土壤中重金属有效态含量显著增加,蕹菜生长不良,株高、鲜重、干重显著降低,同时蕹菜重金属含量增加;添加固化剂后土壤pH值提高了2.21和2.29个单位,土壤有效态重金属含量显著降低,蕹菜株高、鲜重、干重增加,同时使轻度污染土壤上的蕹菜达到卫生安全标准。     

Sustainability of in situ remediation of Cu- and Cd-contaminated soils with one-time application of amendments in Guixi,China

Purpose

In situ immobilization of heavy metal-contaminated soils with the repeated incorporation of amendments can effectively reduce the bioavailability of soil heavy metals. However, the long-term application of amendments would lead to the destruction of soil structure and accumulation of soil toxic elements, ultimately affecting food security and quality. Thus, the sustainability of the amendments in a heavy metal-contaminated soil was evaluated from 2010 to 2012.

Materials and methods

Batch field experiments were conducted in the soils, which were amended with apatite (22.3 t ha^?1), lime (4.45 t ha^?1), and charcoal (66.8 t ha^?1), respectively. The amendments were applied only one time in 2009, and ryegrass was sown each year. Ryegrass and setaria glauca (a kind of weed) were harvested each year. Concentrations of copper (Cu) and cadmium (Cd) were determined by batch experiments. Five fractions of Cu and Cd were evaluated by a sequential extraction procedure.

Results and discussion

Ryegrass grew well in the amended soils in the first year, but it failed to grow in all the soils in the third year. However, setaria glauca could grow with higher biomass in all the amended soils. The treatment of apatite combined with plants was more effective than lime and charcoal treatments in removing Cu and Cd from the contaminated soils by taking biomass into account. Apatite had the best sustainable effect on alleviating soil acidification. The Cu and Cd concentrations of CaCl₂-extractable and exchangeable fractions decreased with the application of amendments. Moreover, apatite and lime could effectively maintain the bioavailability of Cu and Cd low.

Conclusions

Apatite had a better sustainable effect on the remediation of heavy metal-contaminated soils than lime and charcoal. Although all the amendment treated soils did not reduce soil total concentrations of Cu and Cd, they could effectively reduce the environmental risk of the contaminated soils. The findings could be effectively used for in situ remediation of heavy metal-contaminated soils.

     

“In Situ” Amendments and Revegetation Reduce Trace Element Leaching in a Contaminated Soil

Various amendments and/or a plant cover (Agrostis stolonifera L.) were assessed for their potential to reduce trace element leaching in a contaminated soil under semi-arid conditions. The experiment was carried out in field containers and lasted 30 months. Five treatments with amendments (leonardite (LEO), litter (LIT), municipal waste compost (MWC), biosolid compost (BC) and sugar beet lime (SL)) and a plant cover and two controls (control without amendment but with plant (CTRP) and control without amendment and without plant (CTR)) were established. Drainage volumes were measured after each precipitation event and aliquots were analysed for pH, electrical conductivity (EC) and trace element concentrations (As, Cd, Cu, Pb and Zn). Soil pH and trace element extractability (0.01 M CaCl₂) at three different depths (0–10, 10–20 and 20–30 cm) were measured at the end of the experiment. Incorporation of amendments reduced leaching of Cd, Cu and Zn between 40–70% in comparison to untreated soil. The most effective amendments were SL, BC and MWC. At the end of the experiment, extractable concentrations of Cd, Cu and Zn were generally lower in all amended soils and CTRP compared to CTR. Soil pH decreased and extractability of metals increased in all treatments in relation to depth. Results showed that use of these amendments combined with healthy and sustainable plant cover might be a reliable option for “in situ” stabilization of trace elements in moderately contaminated soils.     

典型设施栽培土壤重金属含量变化及其风险评价

采用野外调查采样和室内分析相结合的方法,对典型设施栽培地山东寿光的部分土壤重金属含量进行测定,并根据温室蔬菜产地环境质量评价标准,选取单项污染指数法和尼梅罗综合指数法对土壤的重金属污染状况进行了环境质量评价。结果表明,重金属Cu、C r、Pb在设施栽培土壤耕层(0—20 cm)的含量达最大值,显著高于露地土壤;而设施栽培土壤中Zn和Cd的含量分别在20—40 cm和40—60 cm的土层达到最大值,其中Zn含量在0—20 cm和60—80 cm的土层显著高于露地土壤,Cd含量在0—20 cm,40—60 cm,60—80 cm和80—100 cm的土层显著高于露地土壤。从不同使用年限设施栽培土壤中重金属含量变化看出,重金属在设施栽培24~年的土壤中含量最高。对研究区设施栽培土壤重金属含量进行风险评估及分级发现,山东寿光设施土壤耕层主要受到重金属Cd的污染。     

开封黑岗口引黄灌区稻麦轮作下农田土壤剖面重金属分布特征

引黄灌区是我国重要的农业生产基地,其土壤重金属赋存状况直接关系到农业的可持续发展。本研究以黑岗口引黄灌区开封北郊稻麦轮作下农田土壤为研究对象,采集了耕作层(0~15 cm与15~30 cm)与剖面(0~100 cm)土壤样品,对其土壤剖面主要性质与重金属Pb、Cd、Cu和Zn的积累特征进行了分析。结果表明:(1)长期引黄灌溉及稻麦轮作下,开封北郊农业土壤主要性质在剖面上表现出明显的分异特征:总有机碳(TOC)与全氮(TN)含量主要分布在耕作层土壤,而30 cm以下的土层其含量明显降低;全磷(TP)含量在各土壤层中无明显差异;在部分土壤剖面中CaCO3呈现出明显的淀积层。(2)耕作层(0~30 cm)土壤中重金属Pb、Cu、Zn的含量与研究区背景值相当,而Cd含量显著高于背景值。除少部分剖面含量超标外,Cd、Pb、Cu、Zn的平均含量均未超出WHO限值,且远低于我国农业土壤环境质量标准。因子分析源解析表明:引黄灌区土壤中Pb、Cu和Zn具有相似的来源和迁移特性,而Cd的来源和迁移特性具有特殊性,它可能与当地的化肥施用等农业活动有关。(3)土壤剖面中Cu和Zn具有明显的表聚现象,Pb的表聚作用不明显,而Cd在剖面各层土壤含量具有较大变异性,这与重金属的自身属性、土壤剖面性质和当地的耕作条件有较大相关性。(4)Cu和Zn在土壤剖面主要以有机结合态和残余态形式存在;Pb的残余态、有机态以及铁锰氧化态含量也较高,且Pb的全量与有机结合态含量百分比变化呈现出一定的相似性;而Cd具有较高的碳酸盐结合态和离子交换态,表明Cd在土壤中具有较强的移动性,预示Cd的潜在健康风险较高。     

宁夏不同地区农田土壤磷素养分的空间变异特征

在宁夏灌区和旱区30块农田分别采集了0~120 cm深土壤剖面样品,测定了土壤全磷和速效磷含量,分析了土壤磷素养分含量的空间变异性。结果表明,在0~120 cm深土壤剖面中的全磷和速效磷含量,灌区土壤显著高于旱区土壤,在剖面点之间和土壤层次之间存在极显著差异,而且在土层间还存在着正相关。其变异系数总体上是旱区土壤大于灌区土壤,速效磷大于全磷。从地区来看,旱区土壤全磷和速效磷含量的变异系数随剖面深度的增加而增大,灌区土壤全磷量的变异系数在剖面层次之间差别不大,而速效磷的变异系数随剖面深度的增加而呈降低趋势。在0~120 cm深土壤剖面中,土壤全磷和速效磷的累积量灌区较旱区分别高出26.8%和65.0%,在土类间也存在较大差异。     

长期施肥对砂姜黑土可溶性碳淋溶的影响

研究施肥对砂姜黑土可溶性碳淋溶的影响,对有机肥的可持续利用有重要意义.该研究依托33 a的长期试验,分析常规施肥(MF)、化肥+低量小麦秸秆(MFL)、化肥+高量小麦秸秆(MFH)、化肥+猪粪(MFP)和化肥+牛粪(MFC)等施肥方式对土壤剖面(0～60 cm)理化性质、微生物性状、可溶性有机碳(Dissolved O...     

Immobilization of Cu and Cd in a contaminated soil: one- and four-year field effects

Purpose

Many amendments have been applied to immobilize heavy metals in soil. However, little information is available on the changes of immobilization efficiencies of heavy metals in contaminated soils over time. This work investigated the immobilization efficiencies of copper (Cu) and cadmium (Cd) in contaminated soils in situ remediated with one-time application of three amendments for 1 year and 4 years.

Materials and methods

Apatite, lime, and charcoal were mixed with the topsoil of each plot with the amounts of 22.3, 4.45, and 66.8 t/ha, respectively. Soil chemical properties and fractions of Cu and Cd were examined after in situ remediation for 1 year and 4 years. Soil sorption and retention capacities and desorption proportions for Cu and Cd were investigated by batch experiments.

Results and discussion

The addition of amendments significantly increased soil pH, but decreased exchange acid and aluminum (Al). The amendments significantly decreased the CaCl₂ extractable Cu and Cd and transformed them from active to inactive fractions. After the application of amendments for 1 year, the maximum sorption capacities ranged from 35.6 to 38.8 mmol/kg for Cu and from 14.4 to 17.0 mmol/kg for Cd, which were markedly higher than those of the application of amendments for 4 years (Cu, 29.6–34.7 mmol/kg; Cd, 10.9–16.4 mmol/kg). Desorption proportions (D) of Cu and Cd using three extractants followed the order of \( {D}_{{\mathrm{NaNO}}_3}<{D}_{{\mathrm{CaCI}}_2}<{D}_{{\mathrm{MgCI}}_2} \) . Moreover, the retention capacities (R) of Cu and Cd both increased and followed the order of R _apatite?>?R _lime?>?R _charcoal, resulting in higher Cu and Cd in the amended soils than the untreated soil.

Conclusions

Apatite, lime, and charcoal increased the soil sorption and retention capacities of Cu and Cd and resulted in higher immobilization efficiencies in the amended soils than the untreated soil. However, the immobilization efficiencies of Cu and Cd decreased with the decrease of sorption capacities after 4 years. It was concluded that apatite had the best effect on the long-term stability of immobilized Cu and Cd and can be applied to immobilize heavy metals in contaminated soils.     

生物炭对不同酸化水平稻田土壤性质和重金属Cu、Cd有效性影响

针对南方稻田土壤酸化严重,导致养分流失有毒重金属活化,严重影响稻米质量安全的重大现实问题。以水稻秸秆和谷壳等农业废弃物为原料制备生物炭(分别记为RSC和RHC),研究不同原料生物炭对酸化土壤改良及其对重金属有效性的影响。设置3个生物炭用量(0,20,50 g/kg,分别记为CK、C1、C2),4种土壤酸化水平(pH 4.01,4.25,4.33,4.58,分别记为L1、L2、L3、L4),生物炭与重金属污染土壤共同培养60天后测定土壤pH、全氮、有机质、有效磷、速效钾和有效态Cu、Cd含量。结果表明:RSC对酸化土壤pH的改良效果明显优于RHC,且施炭量越高提高幅度越大,RSC的C2处理使4种酸度水平的土壤pH分别提高了0.68,0.97,1.29,1.71个单位。2种生物炭均能提高土壤的全氮、有效磷、速效钾和有机质含量,其中各施炭处理有机质显著提高,尤以速效钾的增幅最为显著,RSC对4种养分的提高均优于RHC。RHC对土壤有效态Cu含量无显著影响;RSC的C2较C1处理更能降低土壤中有效态Cu含量,使4种酸度水平的土壤分别降低了13.62%,6.57%,4.36%,7.88%。RHC处理的L3、L4土壤中有效态Cd含量显著降低,最大分别降低了13.79%,19.23%。RSC使4种酸度土壤有效态Cd含量最大分别降低了20.00%,25.81%,20.69%,19.23%。相关分析表明,土壤pH与有效态重金属含量呈显著负相关关系。水稻秸秆炭用于改良酸化土壤、降低重金属Cu和Cd有效性的效果更佳,且降低污染土壤中Cd的有效性较Cu好;生物炭对酸化程度越低的土壤pH和有效磷含量的提高以及有效态Cd含量的降低效果较好,而有效态Cu含量的降低效果则在酸化程度越高的土壤中表现更佳;土壤pH是生物炭调控重金属Cu、Cd有效性的主要影响因素。