钝化剂种类和粒径对复合污染土壤镉铅有效态的影响

为探讨钝化剂种类和粒径对重金属污染土壤的钝化效果,采用室内培养的方法,通过添加三个粒径(60～100、100～200、200目)下的四种不同钝化剂(自制无机型钝化剂、石灰+生物质炭、硅藻土、磷矿粉),研究钝化剂种类和粒径对重金属复合污染土壤中有效态Cd、Pb的影响。钝化60 d之后的结果表明,自制无机型钝化剂、生物质炭+熟石灰和磷矿粉均在200目粒径下对土壤有效态Cd的钝化效果最好,较对照分别减少了9.54%、13.93%和11.08%;其中,硅藻土在100～200目的粒径下效果最佳,有效态Cd含量与对照相比降低了22.35%。自制无机型钝化剂、石灰+生物质炭、硅藻土和磷矿粉对土壤有效态Pb的钝化效果都在200目的粒径下最好,有效态Pb含量与对照相比分别减少了17.81%、18.70%、11.54%和22.19%,其中磷矿粉的钝化效果最佳。研究表明,自制无机型钝化剂、石灰+生物质炭和磷矿粉都是粒径越小钝化土壤重金属Cd、Pb效果越好,可能是由于较小粒径更有利于Cd和Pb由活性态向非活性态转化,硅藻土对Cd、Pb的钝化效果在三个粒径处理间差异不显著。     

石灰组配土壤改良剂抑制污染农田水稻镉吸收

为达有效地调控污染稻田水稻糙米对Cd吸收,该研究选取湖南省长株潭地区的湘潭、醴陵和株洲3处不同Cd污染程度田块,研究石灰配施海泡石、钙镁磷肥、有机肥对水稻Cd吸收和累积的影响。结果表明,施用石灰及其组配改良剂均可明显提高土壤pH值,有效降低土壤中酸提取态Cd含量和水稻中Cd含量。与不施用改良剂相比,石灰配施海泡石或有机肥、配施海泡石和有机肥,Cd污染稻田土壤pH值平均升高1.08,0.96和0.93个单位,酸提取态Cd质量分数分别平均降低20.6%,15.6%和21.2%。石灰配施海泡石、有机肥或钙镁磷肥处理下在轻度Cd污染田块中糙米Cd含量较对照分别显著降低了48.3%,46.7%和34.2%,石灰配施有机肥、钙镁磷肥或钙镁磷肥和有机肥处理下在中度Cd污染田块中糙米Cd含量较对照分别显著降低了52.8%,47.8%和37.5%,石灰配施钙镁磷肥和有机肥、有机肥或海泡石处理下在重度Cd污染田块中糙米Cd含量较对照分别显著降低了51.2%,44.6%和42.5%,均低于食品安全国家标准中糙米限量值0.2 mg/kg(GB2762-2017)。相关分析表明,土壤中酸提取态Cd含量与水稻根、茎叶和糙米中Cd含量呈显著正相关关系(P0.05),说明土壤酸提取态Cd含量是影响糙米对Cd吸收的关键因素之一。上述结果说明,石灰配施海泡石、有机肥或钙镁磷肥+有机肥可有效调控污染稻田土壤中Cd进入水稻,实现水稻安全生产。     

施用生物炭和石灰对土壤镉形态转化的影响

通过室内培养试验,比较石灰、生物炭及生物炭和石灰配施3种改良剂作用下镉污染草甸土中土壤镉各形态转化以及pH的影响。结果表明,土壤添加生物炭培养60d,土壤pH呈随时间增加逐渐增加的趋势,而添加石灰和生物炭与石灰配施处理,土壤pH呈现先增加至最大值而后缓缓降低趋于稳定的趋势,但均显著高于对照。各改良剂的施用均显著降低土壤可交换态Cd含量,与CK处理相比,添加生物炭、石灰和生物炭石灰混合改良剂后,土壤可交换态Cd含量分别降低8.6%~13.7%,17.8%~21.7%和18.4%~23.3%。相关分析结果表明,土壤可交换态Cd含量与土壤pH之间均存在极显著的负相关关系(R2=0.74)。土壤添加改良剂后,显著降低土壤可交换态Cd比例,增加碳酸盐结合态、铁锰氧化物结合态、有机结合态和残渣态Cd比例,从而降低土壤重金属的生物有效性。     

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。     

配施硫基肥对夏玉米镉铅累积的阻控效应

该文以府河流域污灌区农田为研究对象,通过田间小区试验研究了5种施肥措施对土壤重金属镉(Cd)、铅(Pb)有效性以及夏玉米(Zea mays L.)对Cd、Pb富集和转运能力的影响。结果表明:与农民常规施肥(CK)相比,尿素、磷酸二铵和氯化钾配施(N-P-K)以及腐殖酸复合肥、尿素和磷酸二铵配施(HA-N-P)的表层土壤Cd、Pb有效性以及夏玉米对Cd、Pb的富集和迁移能力差异均不显著(P0.05)。然而,腐殖酸复合肥、硫酸铵和磷酸二铵配施(HA-S-P)以及硫酸铵、磷酸二铵和硫酸钾配施(S-P-K)2种施肥措施的表层土壤有效Cd含量分别比CK降低了10.60%和6.36%,表层土壤有效Pb含量分别比CK降低了11.49%和6.00%。此外,HA-S-P处理和S-P-K处理夏玉米Pb转运系数分别比CK降低了50.33%和77.10%,且夏玉米籽粒Pb含量分别比CK降低了59.75%和80.43%(P0.05),但各处理间夏玉米对Cd的转运和富集能力差异并不显著,这说明施用硫基肥可有效抑制夏玉米对Pb的富集和转运,但并未影响其对Cd的富集和转运。综上所述,该污灌区轻度Cd、Pb复合污染农田土壤种植夏玉米建议硫酸铵、磷酸二铵和硫酸钾配施,或者腐殖酸复合肥、硫酸铵和磷酸二铵配施。     

生物质炭与氮肥配施降低水稻重金属含量的盆栽试验

针对重金属污染严重的土壤,探索施用氮肥和生物质炭减少水稻重金属吸收的可行性。该研究采用盆栽试验,选用生物质炭、硫硝铵氮肥(简称普通氮肥)和含硝化抑制剂3,4-二甲基吡唑磷酸盐的硫硝铵氮肥(简称3,4-dimethylpyrazolephosphate,DMPP氮肥),设置了5种处理包括对照即未添加氮肥和生物质炭、普通氮肥添加、DMPP氮肥添加、生物质炭+普通氮肥添加和生物质炭+DMPP氮肥添加,研究了不同处理对水稻华航丝苗(Oryza sativa L.)生长和重金属Cu、Zn和Cd吸收特性的影响。结果表明,不配施生物质炭时,DMPP氮肥对水稻籽粒产量无显著(P0.05)影响;生物质炭与普通氮肥或DMPP氮肥配施均能增加水稻籽粒产量:与单施普通氮肥相比,生物质炭与普通氮肥配施水稻籽粒产量显著(P0.05)增加20.3%;与单施DMPP氮肥相比,生物质炭与DMPP氮肥配施水稻籽粒产量显著(P0.05)增加49.3%。与不施肥对照相比,生物质炭与DMPP氮肥配施能降低籽粒Cu、Zn和Cd含量,其籽粒Cu、Zn和Cd质量分数分别显著降低20.0%、21.4%和11.6%。未配施生物质炭时DMPP促进Cu从秸秆向籽粒的转移,配施生物质炭时DMPP促进Cu和Cd从根向秸秆的转移;生物质炭与不同氮肥配施对水稻籽粒/秸秆和秸秆/根Cu、Zn和Cd转运系数的影响因配施氮肥品种不同而存在差异。综上,生物质炭与DMPP氮肥配施可降低籽粒中重金属Cu、Zn和Cd质量分数,促进水稻生长,增加水稻籽粒产量,适宜在多重金属污染稻田施用。     

石灰和硅肥对非污染土壤Cd有效性和花生Cd含量的影响

本文研究了花生盆栽过程中,不同用量石灰及石灰、硅肥配施对非污染土壤有效态Cd和花生籽仁Cd含量的影响。结果表明：（1）在常规施肥条件下,施用石灰及石灰、硅肥配施均能显著提高土壤pH值,同时使得花生叶片细胞膜透性具有降低的趋势;石灰施用量为0.67g·kg-1土时的土壤有效态Cd含量降低了12.6%（显著低于CK）,而石灰、硅肥配施组合对降低土壤有效Cd含量的作用不显著,可能与硅肥中Cd含量较高有关。（2）不同石灰施用量均有降低花生籽仁中Cd含量的趋势,其中石灰施用量为0.67g·kg-1土时花生籽仁Cd含量比CK降低26.1%;但石灰、硅肥配施对降低花生籽仁Cd含量的作用不显著。（3）花生籽仁Cd含量与土壤有效态Cd含量达正相关显著水平,表明土壤Cd有效性是影响花生籽仁Cd含量的主要原因。     

钝化剂对酸性高镉土壤钝化效果及水稻镉吸收的影响

以海泡石、磷酸二氢钾、钙镁磷肥、钢渣、生石灰及生物炭为重金属镉钝化材料,研究钝化剂对湖南省酸性高镉(Cd)稻田土壤及水稻中Cd含量的影响。以土壤pH值和有效态镉作为评价指标,筛选出三种效果较优的钝化剂,通过正交试验进行复配,选择最优的钝化剂配方进行田间验证。结果表明,海泡石、钙镁磷肥、钢渣在施用比例为1%时均可显著提高土壤pH,pH的提升效果排序为钢渣钙镁磷肥海泡石;除钢渣外,其余钝化剂在施用比例为1%时均可不同程度降低土壤有效态Cd含量,钝化效果排序为磷酸二氢钾钙镁磷肥生物炭海泡石生石灰。选取海泡石、钙镁磷肥和磷酸二氢钾复配钝化剂,依据正交试验结果并综合考虑钝化效果、成本及材料易得性,确定钝化剂的最优施用量组合为海泡石500 mg kg-1、钙镁磷肥500 mg kg-1、磷酸二氢钾170 mg kg-1。大田试验结果表明,施用钝化剂后,土壤pH值提高0.5个单位,土壤有效Cd含量降低34.00%,糙米中Cd含量降低19.44%,水稻各器官Cd的富集与迁移系数明显降低,水稻产量明显升高。     

生物炭对水稻-再生稻体系吸收土壤中Cd和Pb的影响

以矿区周边Cd—Pb复合污染的农田土壤为供试材料,设置0,2.5%和5%(w/w)3个生物炭添加处理,通过盆栽试验探讨生物炭对再生稻吸收土壤中Cd和Pb的影响。结果表明,生物炭施加提高土壤pH和有机质含量,使Cd和Pb从移动性较强的弱酸提取态转化为较稳定的可还原态,且土壤CaCl2提取的有效态Cd和Pb含量分别降低33.23%~53.23%和66.52%~91.45%。同时,生物炭抑制Cd在头季和再生季水稻叶到糙米中的迁移,降低Pb从茎到叶和糙米的迁移,从而减少Cd和Pb在糙米中的累积;在5%生物炭处理下,再生季糙米Cd含量为0.15mg/kg,低于食品安全国家标准限量值(0.2mg/kg);Pb含量比对照处理降低68.18%。此外,再生季糙米中Cd和Pb含量低于头季稻糙米中相应的含量。因此,生物炭可以抑制Cd和Pb在再生稻体内的累积,降低糙米的重金属污染风险。     

微生物和生物炭联用对猪粪堆肥后重金属Pb和Cd的钝化效果

为探讨微生物和生物炭联用对畜禽粪便堆肥过程中重金属钝化效果的影响,该文研究生物炭(花生壳炭、木屑炭、玉米秸秆炭)与复合微生物菌剂联用对重金属Pb、Cd形态转化及钝化效果的影响。试验结果表明:9个处理高温期维持天数均达无害化卫生要求,生物炭添加比例对堆肥过程中温度变化影响显著。对Pb的钝化效果最优处理是24%花生壳生物炭和1%的菌剂(T9),可交换态分配率较堆前下降16.32%,钝化效率为74.60%。对Cd的钝化效果最优的处理是24%木屑炭和1.5%的菌剂(T3),交换态Cd与堆前相比下降7.96%,钝化效率为58.13%。统计分析结果表明,重金属Pb、Cd的钝化效果与堆肥过程中平均pH值呈显著正相关,重金属Pb的钝化效果与堆肥过程中温度平均值呈显著正相关,重金属Cd的钝化效果与有机质降解率呈显著正相关。     

Effects of Co-Application of Zeolites and Vermicompost on Speciation and Phytoavailability of Cadmium,Lead, and Zinc in a Contaminated Soil

In this study, we investigated, with pot experiments, whether combined application of zeolites and vermicompost is more effective than single application on plant growth and heavy metals’ uptake in a heavy metal contaminated soil. The results showed that co-application of these amendments decreased zinc (Zn) and cadmium (Cd) availability by their redistribution from plant available forms to organic matter and metal oxide associated fractions. While, the addition of vermicompost and zeolites increased the lead (Pb) concentration significantly in the soluble/exchangeable form as compared with the control. Applying vermicompost individually or in combination with zeolites markedly increased plant biomass. Single zeolites and vermicompost reduced Zn and Pb contents of corn roots and shoots compared to un-treated soil, but less compared to the combined zeolite and vermicompost treatments. The results obtained suggest that co-application of zeolites and vermicompost could be an option for immobilizing Cd, Pb, and Zn in heavy metal contaminated soils.     

稻壳基生物炭对生菜Cd吸收及土壤养分的影响

探讨稻壳基生物炭对Cd污染土壤上叶菜吸收Cd和土壤Cd形态的影响作用,明确稻壳基生物炭对土壤Cd污染的调控效应,可为合理利用稻壳基生物炭降低叶菜Cd含量提供参考。采用盆栽试验,研究了稻壳基生物炭在不同用量水平下对2茬生菜地上部Cd含量、土壤养分含量及Cd赋存形态的影响。结果表明,在5~25 g-kg-1用量范围内,稻壳基生物炭显著降低了2茬生菜地上部和根系Cd含量,且在最大用量25 g-kg-1时效果最好,地上部Cd含量分别比未施稻壳基生物炭的对照处理降低了19.6%和45.8%,根系Cd含量分别降低了36.8%和28.0%。在25 g-kg-1用量水平下,稻壳基生物炭对土壤p H、有效磷、速效钾及有机质含量提升效果明显,但显著降低了土壤碱解氮含量。施加稻壳基生物炭对土壤有效态Cd含量及Cd化学形态也有不同影响。随着稻壳基生物炭用量的增加,土壤NH4OAc提取态Cd含量和弱酸提取态Cd含量显著降低,在用量为25 g-kg-1时,分别比对照降低17.9%和10.4%,可还原态Cd含量无显著变化,可氧化态Cd含量呈减低趋势,残渣态Cd含量增加17.6%。因此推测,提升土壤p H、降低土壤有效态Cd含量、增加残渣态Cd含量可能是稻壳基生物炭降低生菜体内Cd含量的主要原因。稻壳基生物炭可以作为土壤改良剂,抑制Cd污染土壤上叶菜对Cd的吸收,改善土壤养分状况。     

Contribution of arbuscular mycorrhizal fungi and soil amendments to remediation of a heavy metal-contaminated soil using sweet sorghum

Owing to their potential advantages such as waste reduction, recycling, and economic attributes, fast-growing bioenergy crops have the capacity to effectively phytoremediate heavy metal-contaminated soils. However, little is known about the role of microbial and chemical amendments in phytoremediation using bioenergy crops. Here, we studied the contributions of inoculation with the arbuscular mycorrhizal fungus (AMF) Acaulospora mellea ZZ and three soil amendments, i.e., hydroxyapatite (HAP), manure, and biochar, at doses of 0.1% and 1% (weight:weight) to heavy metal phytoremediation using sweet sorghum grown on an abandoned agricultural soil, with environmentally realistic contamination (2.6 mg kg^-1 Cd, 1 796 mg kg^-1 Pb, and 1 603 mg kg^-1 Zn), in a plant growth chamber. Mycorrhizal colonization, plant biomass and metal accumulation, metal availability, and soil pH were determined in harvested seedlings 12 weeks after sowing. The results showed that root colonization by indigenous AMF decreased by 28%-46% with HAP, but increased after manure and biochar applications as compared to the no amendment control (CK). The AMF inoculation increased root colonization rates by 16%-128% and in particular, alleviated the inhibition of HAP. The remediation effects were highly dependent on the amendment type and dose. Among the three soil amendments, HAP was the most effective in promoting plant growth and phytostabilization of Cd, Pb, and Zn and phytoextraction of Cd, particularly at a dose of 1%. Compared to CK, 1% HAP decreased DTPA-extractable Cd, Pb, and Zn concentrations in soil by 31%-43%, 30%-38%, and 22%-23%, respectively. Manure and biochar also exerted positive effects on heavy metal immobilization, as indicated by lower DTPA extractability, but only the 1% manure treatment showed plant growth-promoting effect. The AMF inoculation did not affect plant growth, but increased soil pH and induced synergistic interactions with amendments on the immobilization of Cd and Pb. In conclusion, soil amendments, particularly HAP, produced positive impacts and synergistic interactions with AMF on the phytostabilization of heavy metals using sweet sorghum. Accordingly, sweet sorghum combined with soil amendments and AMF may be an effective strategy for heavy metal phytoremediation.     

养殖废水灌溉下施用生物质炭和果胶对土壤养分和重金属迁移的影响

【目的】 养殖废水中含有丰富的养分,但也含有一定的重金属。本文研究了生物质炭和果胶对养殖废水灌溉下的土壤–植物系统养分和重金属迁移规律的影响,以利用养殖废水中的养分,并对其重金属进行调控。 【方法】 选取新乡市郊区农田土壤为供试土壤,采用根箱试验方法种植玉米。设置根箱土壤中添加1%的生物质炭和果胶,分别灌溉蒸馏水和养殖废水发酵产生的沼液。测定了土壤中养分和重金属的含量,探讨了其在土壤–植物系统的迁移规律。 【结果】 沼液灌溉的植株地上部生长与蒸馏水灌溉无显著差异。果胶相比于生物质炭可以促进植株生长。沼液灌溉时,果胶处理的根系和地上部生物量分别比对照增加了25.38%和31.21%。沼液灌溉普遍降低了根际和非根际土壤的pH,生物质炭处理和果胶处理与对照根际和非根际土壤的pH均无显著差异。沼液灌溉增加了非根际土壤的电导,生物质炭相比于果胶增加了土壤的电导。沼液灌溉增加了土壤全氮、有效磷、速效钾和有机质含量。果胶根际土壤的全磷、碱解氮、有效磷、有效Fe、有效Mn均高于生物质炭处理,生物质炭处理根际和非根际土壤的全钾和速效钾含量均高于果胶处理。沼液灌溉相比于蒸馏水灌溉,增加了植株根、茎中N含量和Ca含量。生物质炭处理植株根茎叶N含量、根茎P含量、茎K含量、根茎叶Ca含量、根茎Mg含量高于果胶处理,但果胶处理养分的转运系数较高。养殖废水灌溉增加了根际和非根际土壤中有效Cu和Zn尤其是Zn的含量。与对照相比,生物质炭降低了根际土壤Cu、Pb、Ni的含量,而果胶增加了它们的含量。沼液灌溉增加了植株根茎叶中Cu、Zn、Pb含量,果胶处理植株根系Cu、Zn、Pb、Cd、Ni含量最高,但向地上部转运较少。 【结论】 在北方碱性土壤灌溉养殖废水发酵产生的沼液时,施用生物质炭和果胶可以提高土壤肥力和植株养分含量,生物质炭通过减少土壤中有效态重金属含量以减少重金属在植物体内累积,果胶虽然增加土壤有效态重金属含量,但可以降低其向地上部的转运,避免了重金属在植物体内的累积。      

盐分胁迫下番茄盐分离子和重金属的分布特征

采用盆栽试验方法研究了不同盐分含量处理下番茄不同器官盐分离子（Na＋、K＋、Ca2＋）和重金属离子（Cd2＋、Pb2＋、Cr2＋、Zn2＋、Cu2＋、Ni2＋）的分布特征,探讨盐分离子对番茄不同器官吸收重金属离子的影响机制,为重金属污染盐渍土壤的农业可利用性评价提供科学依据。结果表明,番茄根、茎、叶和果实Na＋含量均随盐分含量增加而增加;番茄根K＋含量随盐分含量增加小幅上升,茎K＋含量则显著下降,叶K＋含量无显著变化;番茄各器官Ca2＋含量随盐分含量增加无明显变化。番茄根Cd、Pb、Cr、Zn和Cu含量以及番茄茎、叶Cd含量均随盐分含量增加而增加;番茄根Ni含量、番茄茎叶Pb、Cr、Ni、Zn和Cu含量以及番茄果实各重金属含量受盐分含量变化影响不大。因此,土壤盐分含量的增加对番茄根部吸收重金属（Ni除外）有促进作用。     

生物炭与沸石复配对碱性土壤铅镉有效性的影响

【目的】以生物炭单施及其与沸石复配为钝化剂,研究其对铅镉复合污染碱性土壤理化性质及铅镉有效性的影响,以期用钝化技术为碱性土壤重金属污染原位修复提供理论和实践支持。【方法】以河南某金属冶炼厂附近铅(Pb)镉(Cd)污染的碱性菜地土壤(Pb 227.75 mg kg^-1、Cd 3.38 mg kg^-1)为研究对象,采用盆栽试验,研究生物炭单施及其与沸石复配(生物炭∶沸石=1∶1)不同施入量(0、1%、2.5%、5%)对土壤理化性质、土壤Pb、Cd有效态含量、青菜根和叶中Pb、Cd含量以及青菜富集转运Pb、Cd的影响。【结果】与对照相比,生物炭单施及其与沸石复配处理,使土壤pH提高了0.03～0.17个单位,与对照无显著差异,但显著提高了土壤有机质、碱解氮、有效磷和速效钾含量(P <0.05)。土壤有效态Pb、Cd含量随钝化剂施用量增加呈下降趋势,分别下降了10.69%～32.75%和7.63%～26.72%,相同施用量下复配处理效果优于单施处理。生物炭及其复配沸石促进了青菜生长,降低了青菜Pb的含量,根部和茎叶中Pb的含量比对照分别下降了2...     

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。     

Availability and Toxic Level of Cadmium,Lead and Nickel in Contaminated Soils

ABSTRACT

The entry of Cd, Pb and Ni into the environment is a cause of concern due to potential toxicity of these metals to plants, animals, and humans. The present study evaluated the availability of Cd, Pb, and Ni to plants through soils. We examined three soil types (Typic Quartzipsamment (TQ), Xantic Hapludox (XH) and Rhodic Hapludox (RH)) with addition four rates of heavy metals: Cd (0, 2, 4 and 12 mg), Pb (0, 45, 90 and 270 mg) and Ni (0, 20, 40, 120 mg) per kg soil with reference to the corresponding rates defined in soil investigation values of the Brazilian environmental legislation. The availability of Cd, Pb and Ni was higher in the TQ than in XH and RH, and the roots and shoots of corn plants grown in TQ yielded the highest concentrations of toxic metals. Soil extraction with diethylene-triaminepentaacetic acid (DTPA) effectively assessed the bioavailability of Cd and Pb, while soil extractions with Mehlich-1 and aqua regia effectivety evaluated the bioavailability of Ni. The levels at which Cd, Pb, and Ni became toxic for plants were determined via extractioned by Mehlich-1, DTPA, Mehlich-3, and aqua regia. Plant growth was shown to influence heavy metal toxicity, with higher growth rates lowering the toxic effect of the metal. Cd, Ni, and Pb exhibited higher availiability in soils with low clay concentrations and were more easily absorbed by plants in those soils.     

Spectroscopic analyses to study the effect of biochar and compost on dry mass of canola and heavy metal immobilization in soil

This research was conducted to use spectroscopic analysis to evaluate the effect of biochar and compost application on heavy metal immobilization during the canola plants grown in the contaminated soil using X-Ray Diffraction (XRD), Energy Dispersive spectroscopy by X-rays (EDX) and Fourier Transmission Infrared Spectroscopy (FTIR). The results showed that the cadmium (Cd) and lead (Pb) concentrations in the root and shoot of canola plants significantly decreased with the addition of rice straw compost (RC) and biochar (RB) to contaminated soil. The use of spectroscopic analysis observed the precipitation, inner-sphere complex reaction, and electrostatic attraction are the dominating mechanisms for heavy metals immobilization with organic amendments. Our results indicate that the rice straw biochar and compost can immobilize heavy metals and improve dry weight of canola plants. Moreover, the spectroscopic analysis is a simple method and can be effective to understand the mechanism of heavy metals immobilization.