镉污染土壤的植物修复及其EDTA调控研究II. EDTA对镉的形态及其生物毒性的影响

本文通过温室盆栽试验研究了10~200 mg/kg共20个浓度梯度的Cd处理下,EDTA加入土壤后对Cd的形态及其生物毒性的影响。在收获前一周加入EDTA,收获后测定植物根和地上部的生物量,以及H2O、NH4NO3和EDTA 3种提取剂提取的Cd浓度。结果表明,EDTA加入土壤一周后,土壤水溶态Cd增加了400倍以上,交换态Cd增加了40倍以上,印度芥菜根和地上部的生长都受到抑制。可能的原因是EDTA增加了土壤中镉的移动性,提高了Cd对植物的毒性。     

镉污染土壤的植物修复及其EDTA调控研究：Ⅱ．EDTA对镉的形态及其生物毒性的影响

本通过温室盆栽试验研究了10－200mg/kg共20个浓度梯度的Cd处理下，EDTA加入土壤后对Cd的形态及其生物毒性的影响，在获前一周加入EDTA，收获后测定植物根和地上部的生物量，以及H2O、NH4NO3和EDTA3种提取剂提取的Cd浓度。结果表明，EDTA加入土壤一周后，土壤水溶态Cd增加了400倍以上，交换态Cd增加了40倍以上，印度芥菜根和地上部的生长都受到抑制。可能的原因是EDTA增加了土壤中镉的移动性，提高了Cd对植物的毒性。     

重金属污染土壤的植物修复研究Ⅲ.金属富集植物Brassica juncea对锌镉的吸收和积累

采用温室盆栽试验研究了印度芥菜对土壤中锌镉污染的忍耐、积累能力 ,以检验这种植物修复Zn、Cd污染土壤的可能性及其潜力。在加入Zn 5 0 0和 1 0 0 0mgkg- 1 的土壤中 ,印度芥菜生长 66天后 ,叶片中积累Zn的平均浓度分别达 2 80和 662mgkg- 1 ,地上部带走的Zn分别为每盆 2 1 95和 341 2 μg。在加入Cd 2 0 0mgkg- 1 的土壤中生长的印度芥菜 ,叶片中积累Cd浓度为 1 61mgkg- 1 ,地上部带走的Cd为每盆 381 μg。和普通植物相比 ,印度芥菜更能将Zn和Cd从根运输到地上部。Zn 5 0 0mgkg- 1 处理的土壤在种植印度芥菜后其NH4NO3提取的Zn显著高于不种植物的处理 ;土壤添加Cd 2 0 0mgkg- 1 的处理NH4NO3提取的Cd也显著高于不种植物的处理 ,可能的原因是植物根分泌出特殊的分泌物 ,专一性地螯合溶解根系附近的难溶态Zn和Cd,从而提高土壤溶液中的浓度。印度芥菜对Zn、Cd有较强的忍耐和富集能力 ,是Zn、Cd污染土壤修复有潜力的植物。     

铜污染土壤修复的有机调控研究Ⅲ.EDTA和低分子量有机酸的效应

通过盆栽试验研究了EDTA和低分子量有机酸对土壤溶液性质、土壤铜形态变化和印度芥菜生长及铜吸收的影响。结果表明 ,施用pH6.3的EDTA溶液 ( 3mmolkg- 1 )显著地增加了土壤溶液铜 ,特别是难解离态铜的含量 ,其消长规律与土壤溶液TOC的变化相一致 ,也显著地增加土壤NH4NO3提取态和NH4OAc提取态铜量 ,但对芥菜生长没有显著影响。EDTA的加入显著地增加芥菜各组织铜浓度和铜吸收量 ,从而增加了芥菜的铜总吸收量 ,提高了植物修复效率。施用 3mmolkg- 1 pH6.3的草酸、柠檬酸或苹果酸对土壤铜含量及其形态分配和芥菜生长及铜吸收均无明显影响     

印度芥菜对土壤中难溶态镉、铅的吸收差异

通过根际袋法土培盆栽试验，研究了印度芥菜对石灰性土壤中难熔态Cd,Pb的吸收差异。试验结果表明，印度芥菜能吸收石灰性土壤中的难溶态Cd,Pb并对其有较高的忍耐性。印度芥菜吸收的Cd70%以上累只在地上部而吸收的Pb83%以以累积在根系；印度芥菜根际土壤中的DTPA提取态Cd显著高于非根际土壤，但根际与非根际土壤中的DTPA提取的Pb含量差异不显著。本试验条件下，印度芥菜对土壤Cd的净化率为0．83％－1．25％，对土壤Pb的净化率则只有0.04%-0.07%。     

EDTA与EDDS螯合诱导印度芥菜吸取修复重金属复合污染土壤研究

盆栽试验比较研究了EDTA和易降解的EDDS对复合污染土壤中Cu、Zn、Pb、Cd的活化能力及印度芥菜对4种重金属的吸收与转运特征。结果表明:施用量相同的条件下,EDDS活化土壤Cu的能力与EDTA相当;而EDDS活化土壤Zn、Pb、Cd,尤其是活化土壤Pb、Cd的能力小于EDTA,这与两种螯合剂与不同重金属形成螯合物的稳定常数相一致。向复合污染土壤中施入3mmol/kg和6mmol/kgEDDS均可诱导印度芥菜叶中超量积累Cu。本研究中3mmol/kgEDDS的不同施用方式(单次施,分2次和4次施)对印度芥菜叶片Cu含量的影响差异不显著。各处理印度芥菜叶中的重金属浓度要远高于茎中的浓度,茎中的Cu浓度随土壤溶液Cu浓度线性增加,而叶中Cu的浓度随土壤溶液Cu浓度先增加后下降。     

微生物对土壤Cd Pb和Zn生物有效性的影响研究

采用土壤盆栽模拟试验方法,研究了接种不同微生物对重金属富集植物——印度芥菜修复土壤中Cd、Pb、Zn的作用效果。结果表明,接入菌株JA27、JC55、JC40不仅显著促进植物的生长,提高印度芥菜的生物量,降低了土壤pH,并且对土壤Cd、Pb、Zn产生活化作用,使土壤Cd、Pb、Zn有效态含量显著增加,增强印度芥菜对土壤Cd、Pb、Zn吸收量,显著提高了富集植物的修复效果。以上3个处理使印度芥菜地上部Cd、Pb、Zn吸收量分别提高了117%～137%、37%～62%、9%～15.1%。接种JB37对土壤Cd、Pb、Zn产生钝化作用,并且抑制印度芥菜对土壤Cd、Pb、Zn的吸收。JB37处理印度芥菜地上部Pb、Zn吸收量分别降低了72.5%、27%,对Cd吸收量无显著影响。     

印度芥菜对土壤Cd,Pb的吸收富集效应及修复潜力研究

通过盆栽试验对比研究了印度芥菜(Brassica juncea)和油菜对复合污染土壤Cd,Pb的吸收富集效应及修复效率.初步探讨印度芥菜品种Wild Garden Pungent Mix净化重金属污染土壤的应用潜力.结果表明:Cd,Pb复合污染条件下,与油菜相比,印度芥菜对重金属Cd,Pb的抗耐性较强,地上部生物量较大,是同处理油菜的1.1～2.0倍.印度芥菜和油菜对重金属Cd,Pb的吸收富集表现出较为一致的特点,并且对土壤中重金属的吸收能力顺序均为Cd＞Pb,对土壤中Cd的吸收达到了100 mg/kg以上.表现出了超富集植物的特性.但相比之下,印度芥菜对土壤中Cd,Pb的吸收富集能力强于油菜.同时通过多元回归分析表明,两种植物对Cd,Pb的吸收不存在复合效应.本研究中,印度芥菜对Cd的净化率为0.35%～9.22%,是同处理下油菜的2.1～3.5倍;印度芥菜对Pb的净化率只有0.015%～0.356%,虽然是同处理下油菜的1.4～5.5倍,但远小于对Cd的净化率.研究表明,该品种印度芥菜具备应用于修复Cd污染土壤的潜力.     

EDTA对铅污染土壤上芥菜生长及铅积累特性的影响

采用盆栽实验研究了EDTA对Pb污染土壤上芥菜生长及Pb积累特性的影响。结果表明,单独Pb处理对芥菜生物量没有明显的影响,但高Pb处理(2000mg kg-1 Pb)芥菜地上部含水量显著降低;Pb处理芥菜体内Pb含量随土壤Pb浓度的增加而明显增加,根系Pb含量高于地上部Pb含量;3mmol kg-1 EDTA处理能促进土壤Pb溶解,增加土壤有效Pb含量,影响芥菜的正常生长,芥菜地上部生物量下降,高Pb浓度处理比低Pb浓度处理更明显;EDTA处理14天芥菜地上部和根系Pb积累量都比不加EDTA的对照明显增加,地上部Pb总量增加到对照的13.1～80倍;EDTA处理芥菜地上部与根系Pb含量的比值上升,表明EDTA处理促进Pb向地上部运输,这种促进作用因土壤Pb浓度的不同而略有差异。     

镉污染土壤的植物修复及其EDTA调控研究I. 镉对富集植物印度芥菜的毒性

本文通过温室盆栽试验研究了在10~190 mg/kg共10个浓度梯度的Cd处理下,印度芥菜生长对Cd的响应、Cd在根与地上部的积累以及在Cd胁迫和毒害条件下对Ca和Zn吸收的影响。结果表明,Cd对印度芥菜生长的毒害浓度在各个生育期各有不同:幼苗期与营养生长前期在70~110 mg/kg左右;营养生长后期在110 mg/kg以上;成熟期在150 mg/kg左右。植物吸收的镉随土壤镉处理浓度的增加而增加,本试验中印度芥菜根和叶积累镉最高浓度分别为300 和160 mg/kg。在Cd胁迫下,印度芥菜吸收的Ca和Zn增加;在Cd毒害条件下,印度芥菜吸收的Ca和Zn下降。认为高浓度的Cd对印度芥菜生长有抑制,但印度芥菜对镉也表现出很强的耐性,这种耐性可能与植物体内Cd和Ca、Zn之间的平衡有关。     

根迹土壤根诱导的化学变化对植物吸收重金属的影响

It is increasingly recognized that metal bioavailability is a better indicator of the potential for phytoremediation than the total metal concentration in soils; therefore, an understanding of the inffuence of phytoremediation plants on metal dynamics at the soil-root interface is increasingly vital for the successful implementation of this remediation technique. In this study, we investigated the heavy metal and soil solution chemical changes at field moisture, after growth of either Indian mustard (Brassica juncea) or sunffower (Helianthus annuus L.), in long-term contaminated soils and the subsequent metal uptake by the selected plants. In addition, the fractions of free metal ions in soil solution were determined using the Donnan membrane technique. After plant growth soil solution pH increased by 0.2-1.4 units and dissolved organic carbon (DOC) increased by 1-99 mg L^-1 in all soils examined. Soluble Cd and Zn decreased after Indian mustard growth in all soils examined, and this was attributed to increases in soil solution pH (by 0.9 units) after plant growth. Concentrations of soluble Cu and Pb decreased in acidic soils but increased in alkaline soils. This discrepancy was likely due to a competitive effect between plant-induced pH and DOC changes on the magnitude of metal solubility. The fractions of free Cd and Zn ranged from 7.2% to 32% and 6.4% to 73%, respectively, and they generally decreased as pH and DOC increased after plant growth. Metal uptake by plants was dependant on the soil solution metal concentration, which was governed by changes in pH and DOC induced by plant exudates, rather than on the total metal concentrations. Although plant uptake also varied with metal and soil types, overall soluble metal concentrations in the rhizosphere were mainly inffuenced by root-induced changes in pH and DOC which subsequently affected the metal uptake by plants.     

Phytoextraction of Pb and Cd from a contaminated agricultural soil using different EDTA application regimes: Laboratory versus field scale measures of efficiency

Enhanced phytoextraction of heavy metals using chelating agents and agricultural crops is widely discussed as a remediation technique for agricultural soils contaminated with low mobile heavy metals. In this study, phytoextraction efficiency of Zea mays after single and split applications of EDTA was tested on the laboratory and the field scale. EDTA effectively increased the mobility of target heavy metals (Pb and Cd) in the soil solution. Split applications provided generally lower water-soluble levels of Pb and Cd both in the pot and the field experiment. Therefore, the risk of groundwater contamination may be reduced after split applications. Higher Pb and Cd mobilisation after single applications increased plant stress, phytotoxicity and reduced plant dry above-ground biomass production compared to corresponding split doses. Single doses enhanced plant uptake of Pb and Cd and the phytoremediation efficiency compared to corresponding split doses. Results of plant dry above-ground biomass and heavy metal uptake obtained from the pot experiment could be to some extent verified in the field experiment. Plant uptake of Pb and Cd was lower and biomass production dropped after EDTA additions in the field experiment. Remediation factors in the field experiment were in general significantly lower than in the pot experiment mainly due to the much higher mass of soil per plant under field conditions. This highlights the limitations when going from the lab to the field scale. The low phytoremediation efficiency in the field and the mobilisation of high amounts of Pb and Cd down the soil profile may make the use of EDTA and Z. mays not suitable for the remediation of severely heavy metal contaminated soils in a reasonable time frame and may result in substantial groundwater pollution under used crop management.     

酸性土壤上伴矿景天铝毒的缓解技术研究

酸性土壤上易产生铝（Al）毒害作用，缓解Al毒对于污染土壤上超积累植物的生长及重金属有效削减具有重要意义。本研究比较了不同措施对镉（Cd）超积累植物伴矿景天的Al胁迫缓解作用，结果发现：① 在水培条件下，锌添加可促进了Al胁迫下伴矿景天根表Cd2+吸收速率，而添加氯化钙或柠檬酸没有显著的缓解作用；② 在盆栽试验条件下，添加石灰处理显著提高了土壤pH，促进了伴矿景天生长和地上部对Cd的吸收，但添加生物质炭或柠檬酸没有显著缓解Al毒对伴矿景天生长和Cd吸收的抑制，添加柠檬酸反而加剧了土壤酸化，提高了土壤Al的活性；③在伴矿景天与荞麦间作条件下，其一定程度上降低了土壤的Al活性，在合适的种植密度下并未显著影响伴矿景天单株地上部Cd吸收量。综上，酸性土壤上耐Al作物与修复植物间作、结合添加改良剂调控Al毒，能够不显著降低土壤Cd的有效性和修复植物的Cd吸收，进而实现污染土壤的边生产边修复。     

Humic Acids Increase the Phytoavailability of Cd and Pb to Wheat Plants Cultivated in Freshly Spiked, Contaminated Soil (7 pp)

Background, Aim and Scope   Humic acids (HAs) are the most important humified component of dissolved organic carbon (DOC) present in sewage water used for irrigation. It is well known that HAs affect the toxicity and availability of heavy metals (HMs) in soil-plant systems, and may increase the human exposure to HMs in contaminated soil through plant uptake. This study was conducted to assess the effects of HAs on HM availability, plant growth and HM uptake. Materials and Methods: With wheat (Triticum aestivum) as a test plant, a greenhouse pot experiment was conducted to investigate the effects of HAs in irrigation water on the phytoavailability of cadmium (Cd) and lead (Pb) in soil. Cd and Pb were added to the soil at concentrations of 1.5 and 150 mg/kg, respectively. Wheat seedlings grown in Cd and Pb-contaminated soil were watered with 4 levels of HA solution (0, 140, 280 and 560 mg/kg of HAs, respectively). Results: In control and Pb treatments, both plant biomass and plant HM concentrations increased with increasing concentrations of HAs in the solution. Plant biomass was markedly decreased when metal concentrations in plants increased, particularly in Cd and Cd/Pb treatments. In the soil, extractable metals, and water soluble organic carbon (WSOC) and its fractions significantly increased with increasing HA concentrations. Discussion: The results suggested that the application of HAs in barren soils may improve plant nutrition by mobilizing soil nutrients and providing plants with carbon sources. On the other hand, HAs present in sewage water may increase both the availability and transfer of HMs in the soil-plant continuum and subsequently increase human exposure to HMs in polluted soil. Conclusions. Conclusions: HA solution as irrigation water significantly increased HM availability to plants cultivated in the HM-amended soil and may increase the environmental risk of sewage irrigation. Recommendations and Perspectives: These results suggested that, when assessing the effect of sewage irrigation on soil quality, HAs contained in sewage water should be taken into consideration.     

Heavy-Metal Phytoextraction Potential of Spinach and Mustard Grown in Contaminated Calcareous Soils

Laboratory batch and greenhouse pot experiments were conducted to determine the extraction efficiency of ethylenediaminetetraacetic acid (EDTA) for solubilizing lead (Pb) and cadmium (Cd) and to explore the natural and chemically induced Pb and Cd phytoextraction efficiencies of spinach and mustard after EDTA application. The EDTA was applied at 0, 1.25, 2.5, and 5.0 mM kg^?1 soil in three replicates. Addition of EDTA increased significantly the soluble fraction Pb and Cd over the control and maximum increases for Pb (1.42- and 1.96-fold) and Cd (1.45- and 1.38-fold) were observed with the addition of 5.0 mM EDTA kg^?1 in Gujranwala and Pacca soils, respectively. Similarly, addition of EDTA increased significantly the Pb and Cd concentrations in the plant shoots, soil solution, bioconcentration factor, and phytoextraction rate. Mustard exhibited better results than spinach when extracting Pb and Cd from both contaminated soils.     

石灰与磷肥可以降低华南5种常见蔬菜对镉的吸收量

A pot experiment was conducted in artificially Cd-contaminated (5 mg Cd kg-1) soils to investigate the feasibility of using lime (3 g kg-1) or phosphate (80 mg P kg-1) to mitigate uptake of Cd by vegetables.Five common vegetables in South China,including lettuce (Lactuca sativa L.var.ramosa Hort.),Chinese cabbage [Brassica rapa L.subsp.Chinensis (L.) var.parachinensis (L.H.Bailey) Hanect],Chinese broccoli (Brassica oleracea L.var.albiflora Kuntze),white amaranth (Amaranthus tricolor L.) and purslane (Amaranthus viridis L.),were grown in the soils and harvested after 60 d.The results showed that liming significantly reduced Cd uptake by most vegetables by 40%-50% (or a maximum of 70%),mainly due to immobilization of soil Cd.Increased availability of Ca in the soil might also contribute to the Cd uptake reduction as a result of absorption competition between Ca and Cd.Liming caused biomass reduction in white amaranth and purslane,but did not influence growth of the other vegetables.Phosphate decreased Cd uptake by vegetables by 12%-23%.Compared with lime,phosphate decreased,to a smaller extent,the bioavailability of Cd in most cases.Phosphate markedly promoted growth of vegetables.Changes in soil chemistry by adding lime or phosphate did not markedly influence nutrient uptake of vegetables except that lime increased Ca content and phosphate increased P content in shoots of the vegetables.The results suggested that a proper application of lime could be effective in reducing Cd uptake of vegetables,and phosphate could promote growth of the vegetables as well as alleviate the toxicity of Cd.     

间作条件下螯合剂对龙葵和大叶井口边草吸收重金属的影响

用室内土培试验方法,在采自田间的Pb、Cd和As复合污染土壤中单作或间作龙葵和大叶井口边草条件下,筛选出修复Pb-Cd-As复合污染土壤较好的种植方式为间作。进一步在间作方式下,研究了外源添加不同浓度EDDS（乙二胺二琥珀酸）、NTA（氨三乙酸）和EDTA（乙二胺四乙酸）对植物吸收Pb、Cd和As的影响。结果表明,间作显著促进了龙葵地上部对Cd的吸收量和大叶井口边草地上部对As的吸收量,间作龙葵地上部吸收Cd和大叶井口边草地上部吸收As含量分别是单作龙葵和大叶井口边草的1.3倍和1.4倍,说明间作龙葵和大叶井口边草比单作更有利于修复Pb-Cd-As复合污染土壤。间作条件下,大叶井口边草对螯合剂的耐性比龙葵更强。3、6、12mmol.kg-1EDTA能极显著增加土壤中Pb、Cd有效态含量,从而促进龙葵地上部对Pb吸收和大叶井口边草地上部对Pb、Cd吸收。EDTA比NTA具有更强的提高土壤Pb、Cd有效态的能力,但对土壤As有效态促进作用与EDTA相比,NTA效果极显著,1.5、3mmol.kg-1NTA处理极显著提高土壤As有效态含量及促进龙葵和大叶井口边草地上部对As吸收。     

胶质芽孢杆菌对印度芥菜富集土壤Cd的效果

通过灭菌土培试验研究分别接种0,12.5,25,37.5,50,62.5ml/盆活菌浓度为1×109 cfu/ml的胶质芽孢杆菌,对印度芥菜修复Cd污染土壤的作用效果。结果表明,接入胶质芽孢杆菌菌液25ml/盆时,植物地上、地下部分对Cd的提取量分别为其他接种量的1.10～1.48倍,1.32～1.77倍。以不种印度芥菜作为对照,种印度芥菜处理的土壤Cd随着时间的变化去除效果有所不同,接菌后14d左右土壤Cd含量最低,收获时土壤Cd去除率可达到20%,显著提高其植物修复效果。同时,不同浓度的胶质芽孢杆菌均可以促进富集植物的生长,印度芥菜地上、地下部分生物量分别提高3%～16%,4%～61%。综上,胶质芽孢杆菌不但可以提高污染土壤中Cd的生物有效性,而且可明显促进超富集植物生长。     

植物吸取修复及钝化处理对后茬水稻镉吸收的影响

采集湖南湘潭县某地镉(Cd)污染酸性农田土壤及其经伴矿景天分别吸取修复两季和三季后的土壤,采用盆栽试验研究了经伴矿景天修复及钝化改良与否对土壤pH、有效态Cd、Zn以及水稻生长和稻米Cd、Zn浓度的影响。结果表明:未改良的处理,随着修复次数的增加,土壤pH显著降低,降低幅度为0.26~0.38个单位;且修复两季、三季土壤CaCl_2提取态Cd浓度较未修复土壤分别降低19.4%、24.0%;修复后土壤种植水稻品种W184,其糙米中Cd浓度显著降低,但依然超标;修复三季土壤种植低积累水稻品种IRA7190,其糙米中Cd由0.47 mg/kg降为0.03 mg/kg。施加钝化剂海泡石和石灰(10 g/kg+1 g/kg)后,修复两季、三季土壤的pH显著升高,较未施钝化剂处理土壤pH分别提高0.95、0.72;土壤CaCl_2提取态Cd浓度分别降低79.8%、79.5%;修复两季、三季土壤上水稻W184糙米的Cd浓度与未施加钝化剂相比,分别降低27.3%、44.4%,均降至国家食品安全限值0.2 mg/kg以下;无论是否添加钝化剂,伴矿景天吸取修复三季的土壤上水稻IRA7190糙米中Cd浓度均仅0.03 mg/kg。