印度芥菜和香根草对Pb污染土壤的修复效能及作用途径

为探究印度芥菜(Brassica juncea)和香根草(Vetiveria zizanioides L.)对Pb污染土壤的修复效能和作用途径,采用Pb污染土壤〔w(Pb)为400~2 000 mg/kg〕进行为期30 d的盆栽试验,分析植物对Pb的耐受性、积累能力和固定效果.结果表明:① 印度芥菜和香根草对Pb的积累主要集中在根部,两种植物根部累积的w(Pb)分别为206.62~902.40和288.42~1 102.47 mg/kg,单株植物的Pb积累量分别为70.75~138.31和99.09~220.49 μg,香根草对Pb污染土壤的修复效能高于印度芥菜. ② 印度芥菜和香根草对Pb的去除率随土壤中w(Pb)的增加而降低,对Pb的固定率则随土壤中w(Pb)的增加而增加,二者对Pb的去除率最大值分别为1.02%和1.78%,对Pb的固定率可达11.22%和16.78%,两种植物对Pb污染土壤修复的主要途径为植物固定. ③ 主成分分析表明,w(脯氨酸)对植物Pb积累过程具有重要作用.研究显示,相比于印度芥菜,香根草更适用于Pb污染土壤的植物修复.      

Selection of appropriate organic additives for enhancing Zn and Cd phytoextraction by hyperaccumulators

Chelant-enhanced phytoextraction is one of the most promising technologies to remove heavy metals from soil. The key of the technology is to choose suitable additives in combination with a suitable plant. In the present study, laboratory batch experiment of metal solubilization, cress seeds germination were undertaken to investigate the metal-mobilizing capability and the phytotoxicity of organic additives, including ethylene diamine triacetic acid （EDTA）, citric acid, acetic acid, oxalic acid, glutamine and monosodium glutamate waste liquid （MGWL） from food industry. Experiments in pots were carried out to study the effects of the additives on Zn and Cd phytoextraction. Furthermore, a leaching experiment with lysimeter was performed to evaluate the environmental risks of additive-induced leaching to underground water. The results showed that EDTA had a strong mobilizing ability for Zn and Cd, followed by mixed reagent （MR） and MGWL. MGWL and acetic acid at 5 mmol equivalent per liter resulted in seed germination index less than 2%. Experiments in pots verified the phytotoxicity of acetic acid and MGWL. Addition of the mixed reagent at 6--10 mmol/kg significantly increased Zn phytoextraction by Thlaspi caerulescens. The same for EDTA and the mixed reagent at 10 mmol/kg by Sedum dfredii. But only mixed reagents could significantly increase Cd phytoextraction by the studied hyperaccumulators. This suggested that the strong chelant was not always the good agent to enhance phytoextraction. S. alfredii combined with 2--10 mmol/kg soil MR was preferred for phytoremediation of Cd/Zn contaminated soils in southern China, this could result in high phytoextraction of Cd/Zn and reduce the leaching risk to underground water than EDTA assisted phytoextration.     

Evaluation of phytoextracting cadmium and lead by sunflower, ricinus, alfalfa and mustard in hydroponic culture

Soil contaminated with heavy metals cadmium(Cd)and lead(Pb)is hard to be remediated.Phytoremediation may be a feasible method to remove toxic metals from soil,but there are few suitable plants which can hyperaccumulate metals.In this study,Cd and Pb accumulation by four plants including sunflower(Helianthus annuus L.),mustard(Brassica juncea L.),alfalfa(Medicago sativa L.), ricinus(Ricinus communis L.)in hydroponic cultures was compared.Results showed that these plants could phytocxtract heavy metals, the ability of accumulation differed with species,concentrations and categories of heavy metals.Values of BCF(bioconcentration factor)and TF(translocation factor)indicated that four species had dissimilar abilities of phytoextraction and transportation of heavy metals.Changes on the biomass of plants,pH and Eh at different treatments revealed that these four plants had distinct responses to Cd and Pb in cultures.Measurements should be taken to improve the phytoremediation of sites contaminated with heavy metals,such as pH and Eh regulations,and so forth.     

高粱修复柴油污染土壤过程中植物生物量及土壤微生物总量的变化

通过温室盆栽试验,研究了高粱修复柴油污染土壤过程中植物生物量及土壤微生物总量的变化情况.通过定量分析土壤中柴油含量对高粱生物量和土壤微生物总量的影响,揭示柴油对土壤环境的生物学效应.结果表明,柴油污染胁迫下高粱的发芽率、存活率以及生物量受到不同程度的影响,在w(柴油)为0.1%的土壤中高粱的发芽率、存活率以及生物量与空白相比约有10%的增加,而在w(柴油)高于3.0%的污染土壤中高粱无法生长.土壤中微生物量随着土壤中柴油含量的增大而减小,但是随着修复过程的进行,土壤环境得到改善,土壤中微生物量有了明显的提高.      

重金属污染土壤的植物修复及其机理研究进展

土壤污染是急需解决的环境问题,植物修复技术利用超积累植物吸收土壤中的重金属,达到清除土壤重金属污染。介绍了植物修复技术方法和植物修复的作用机理及研究进展,植物修复技术方法主要包括植物萃取技术、植物转化技术、植物挥发技术和植物稳定技术;植物修复的作用机理主要包括植物吸收重金属的生理学、分子生物学机理,重金属在植物体内亚细胞分布和化学形态,植物对根际土壤重金属的活化以及植物体内的金属有机配位体的研究进展。     

多氯联苯污染土壤的豆科-禾本科植物田间修复效应

选择豆科植物紫花苜蓿、禾本科植物黑麦草和高羊茅作为供试植物,初步探讨了这3种植物在单作和间作条件下对多氯联苯污染土壤的田间修复效应.结果表明,经过270 d的田间原位修复后,所有种植植物的处理中土壤多氯联苯的去除率均高于对照组,其中紫花苜蓿单作处理土壤中多氯联苯的去除率最高,达到59.6%.土壤多氯联苯同系物分析结果表明,所有种植植物的处理都降低了土壤中二氯联苯的比例.3种植物中紫花苜蓿的生物量最大,其根部积累的多氯联苯含量最高可达355.1μg/kg,显著高于黑麦草和高羊茅根中的含量.各处理对土壤中多氯联苯的提取修复效率依次为:紫花苜蓿单作紫花苜蓿-黑麦草-高羊茅间作紫花苜蓿-黑麦草间作黑麦草单作紫花苜蓿-高羊茅间作高羊茅单作.豆科植物紫花苜蓿是多氯联苯污染土壤田间原位修复的理想材料.     

5种矿区土著植物对铅污染土壤的修复潜力研究

为评估我国西北某矿区茵陈蒿、蒲公英、苜蓿、大叶苦菜和车前草5种土著作物对含铅（Pb）土壤的修复潜力,采用盆栽实验,设置4种不同Pb含量水平（0、2‰、3‰和5‰,质量分数）,测定作物不同组织器官中和种植前后土壤中Pb含量,以及根际与非根际土壤微生物生物量碳含量、过氧化氢酶活性等指标。结果表明:茵陈蒿和车前草适合种植于铅含量为2‰、3‰、5‰的土壤中,可去除12%~32%的土壤Pb,车前草根系和茵陈蒿茎叶对Pb的累积量最高分别达到3617,720 mg/kg,显著高于其他植物,作为土壤铅污染修复植物的潜力较大。根际土壤微生物生物量碳含量比非根际土壤微生物生物量碳含量高2.37%~13.89%。土壤Pb抑制了根际与非根际土壤过氧化氢酶活性,使其活性低于对照组0.44%~22.3%,根际土壤过氧化氢酶活性比非根际过氧化氢酶活性高0.89%~8.09%。研究结果可为Pb污染矿区废弃地植物修复和土壤环境质量评价提供理论依据。     

EDDS对土壤铜镉有效性及蓖麻吸收转运的影响

为探究螯合剂对植物吸收重金属的影响,以蓖麻（Ricinus communis L.）为供试植物,通过土培和盆栽试验,研究不同含量乙二胺二琥珀酸（EDDS）对土壤中铜镉形态和植物吸收、转运的影响.结果表明,EDDS显著增加了土壤有效态铜和镉含量,培养15 d时,增幅分别为43.01%~103.55%和51.78%~69.43%,同时促进了可还原态铜向弱酸提取态转化,增加了土壤铜的移动性.EDDS促进了蓖麻对铜的吸收、转运与富集.EDDS 2.5和EDDS 5.0处理时,地上部铜含量是对照的4.88倍和16.65倍（P< 0.05）,根部是对照的2.89倍和3.60倍（P<0.05）,铜转运系数显著提高了72.73%和381.82%.EDDS 5.0处理时,蓖麻地上部和根部的铜提取量分别是对照处理的14.08倍和2.16倍,总铜提取量是对照处理的4.70倍（P< 0.05）.此外,EDDS显著增加了蓖麻镉含量,EDDS 2.5处理时,地上部和根部分别增加了15.15%和57.42%,蓖麻总镉提取量显著提高了13.44%.综上可知,EDDS能增加土壤铜镉的有效性,促进蓖麻对铜镉的吸收,提高蓖麻的修复效率,其中5.0 mmol·kg^-1 EDDS更有利于蓖麻对铜的提取,而2.5 mmol·kg^-1 EDDS处理对镉的提取有较高的增加效果.     

重金属污染土壤螯合诱导植物修复研究进展

土壤重金属污染来源广泛、危害严重,已经成为环境污染治理中的热点、难点问题。重金属污染土壤螯合诱导植物修复技术是在化学修复、植物修复的基础上发展起来的,具有绿色环保、经济高效等优点,在重金属污染土壤修复领域具有很大的发展空间。本文在综合螯合诱导植物修复技术发展概况的基础上,系统介绍了螯合剂种类、螯合剂施入时间、施入方式、浓度与剂量、不同富集植物以及土壤理化性质等对重金属污染土壤修复效果的影响及国内外研究概况,综述了螯合诱导植物修复技术的作用机理及其环境风险研究进展。最后,提出了重金属污染土壤螯合诱导植物修复技术还有待深入研究的有关问题。     

石油污染土壤多酚氧化酶的动力学及热力学特征

土壤多酚氧化酶是一种氧化还原酶,能够将土壤中芳香族化合物氧化成醌,促进土壤中石油类物质的分解转化.以距大庆油田工作区不同距离（1、5、15 km）的石油污染地为对象,研究不同温度下石油污染裸地及羊草（Leymus chinensis）修复地的土壤多酚氧化酶活性及其动力学和热力学特征的变化.结果表明:土壤多酚氧化酶活性随温度和底物浓度的增加而逐渐增大,在温度为30℃或40℃、底物浓度为80 mmol/L或160 mmol/L时达到最大值;各样地土壤酶的动力学参数K_m（Mihaelis常数）随温度的变化规律不同,V_max（酶促反应最大速度）和V_max/K_m（催化效率）随温度升高而逐渐增大,均在30℃或40℃时达到最大值;热力学参数Q₁₀（温度系数）、ΔH（活化焓）、ΔS（活化熵）随温度变化差异不显著,ΔG（活化自由能）随温度升高呈逐渐增加趋势.在同一温度下,石油污染裸地土壤多酚氧化酶活性高于羊草修复地;K_m和V_max/K_m在各样地均表现为无规律性变化,V_max最大值出现在距油田工作区5 km处的裸地（BMP）,最小值出现在距油田工作区5 km处的羊草修复地（LMP）;Q₁₀、E_a（活化能）、ΔH、ΔS的最大值均出现在距油田工作区1 km处的裸地（BVP）,最小值均出现在距油田工作区1 km处的羊草修复地（LVP）.研究显示,升温和植物修复对土壤多酚氧化酶活性的反应特征有较大影响.      

重金属污染土壤的植物修复研究现状

植物修复是利用植物吸收、降解、挥发、根滤、稳定等作用机理,达到去除土壤、水体中污染物,或使污染物固定以减轻其危害性,或使污染物转化为毒性较低化学形态的现场治理技术。植物修复对于重金属污染土壤的治理修复具有重要意义。已有研究在累积与超累积植物的寻找筛选、植物对重金属等有害物的耐毒和解毒机理、植物修复现场环境调控及根际处理技术等方面取得了大量成果。     

两种外源有机酸对土壤Cd形态及秋华柳Cd积累的影响

秋华柳(Salix variegate Franch.)因具有良好的重金属耐受和积累能力,常被作为重金属污染土壤修复工程物种.通过盆栽模拟试验,分析了不同浓度外源草酸和酒石酸处理下土壤Cd形态的变化和秋华柳Cd含量的积累特征,以探究外源有机酸在Cd污染土壤植物修复中的应用潜力.结果表明:添加外源酒石酸可显著降低土壤非有效性Cd含量,增加土壤中以可交换态Cd为主的有效性Cd含量,促进了秋华柳对Cd的积累,同时也显著提升了植株的富集系数,其中添加5 mmol/kg酒石酸的处理效果最佳.与CK相比,添加5 mmol/kg外源酒石酸可显著增加秋华柳根、茎和叶中的Cd积累量,地上、地下部分和全株的Cd积累量分别提升了62.2%、75.9%和78.4%,地上和地下部分富集系数分别提升了173.0%和178.8%.添加外源草酸对土壤有效性Cd含量没有显著影响,秋华柳根、茎和叶的Cd含量和积累量无明显提升.研究显示,添加较低浓度的酒石酸更有利于增加土壤中可交换态Cd含量和有效性Cd含量,促进秋华柳对土壤中Cd的吸收和积累,增强秋华柳对Cd污染土壤的修复能力,可应用于Cd污染土壤的植物修复.      

超积累植物龙葵及其对镉的富集特征

超积累植物筛选是重金属污染土壤植物提取修复的基础和核心问题,同时也是污染环境植物修复的难点及前沿.杂草具有抗逆境能力强、生长迅速、繁殖能力强以及在环境条件适宜情况下生物量能够急剧提高等特点,可以弥补现有超积累植物的某些缺点和不足,是较理想的超积累植物资源.本文通过室外盆栽模拟试验及重金属污染区采样分析试验,首次发现并证实杂草龙葵(Solanumnigrum L .)是一种Cd超积累植物.其中,盆栽试验表明,在Cd污染水平为25mg/kg条件下,龙葵茎及叶的Cd含量分别超过了100mg/kg这一公认Cd超积累植物应达到的临界含量标准,其地上部Cd含量大于其根部Cd含量,且地上部Cd富集系数大于1 ,同时,与对照相比,植物的生长未受到抑制.污染区采样分析试验进一步表明,龙葵对Cd的富集符合Cd超积累植物的基本特征.这一通过未污染区对超积累植物进行筛选的方法,可以为Cd污染土壤的植物修复获得更多具有实用价值的新材料.     

螯合剂、菌根联合植物修复重金属污染土壤研究进展

植物修复作为一种原位绿色修复技术,成为污染土壤修复研究的重点。然而,目前最具推广价值的超积累植物植株矮小、生物量低、生长缓慢、生活周期长及对重金属积累的专一性,大大限制了植物修复技术在重金属污染土壤修复方面的应用。因此利用生长速度快、生物量大的普通植物借助其他的技术辅助的联合植物修复成为了有效可行的替代途径。近年来,国内外对螯合剂和菌根在强化植物修复中的应用进行了大量的研究,文章在综述螯合剂、菌根在强化植物修复研究中的应用的基础上,综述了螯合剂和菌根两者联合在强化植物修复重金属污染土壤中的应用,并对重金属污染土壤修复的未来研究方向进行了展望。     

向日葵对锶的富集特征与耐受机制研究

为探明向日葵(Helianthus annuus L.)对金属锶的富集特征和耐受机制,本试验施加不同浓度锶(25、150、750和1500 mg·kg-1)土培处理30 d,研究了向日葵幼苗体内锶的富集和分配特征及对植物生长和膜脂过氧化产物MDA(丙二醛)含量、SOD(超氧化物歧化酶)、POD(过氧化物酶)、CAT(过氧化氢酶)活性的影响.结果显示:(1)向日葵幼苗的根长、株高、根生物量和地上生物量随着土壤中金属锶浓度的升高呈先增加后降低的趋势;(2)向日葵的根、茎、叶均能富集金属锶,不同器官表现为根叶茎.向日葵的生物富集系数与不同器官金属锶富集浓度呈显著负相关,且根部金属锶浓度与富集系数的相关性最强;(3)MDA含量随着锶浓度升高呈先减少后增加的趋势,而抗氧化酶SOD、POD和CAT活性均随着锶浓度升高呈先增加后减少的趋势.SOD和POD活性在高浓度金属锶处理中受到了抑制,而高水平的CAT活性表明向日葵清除活性氧的能力增强.以上结果表明,向日葵的根、茎、叶均能积累锶,根部的富集能力最强,且根部的抗氧化酶系统对金属锶胁迫更为敏感,其中较高的CAT活性表明在向日葵耐受锶胁迫机制中起到关键作用.此研究为金属锶污染土壤的植物修复以及向日葵对锶的耐受机制提供理论依据.     

4种草本植物对氯代有机磷酸酯阻燃剂污染土壤的修复能力研究

以4种常用的有机污染土壤修复植物高羊茅(Festuca arundinacea)、黑麦草(Lolium perenne L.)、苕子(Vicia villosa Roth var)和紫花苜蓿(Medicago sativa L.)为研究材料,通过盆栽试验考察了4种草本植物在磷酸三(1-氯-2-丙基)酯[tris-(1-chloro-2-propyl) phosphate, TCIPP]污染土壤胁迫下的耐受和富集特征,以期筛选出具有一定TCIPP污染土壤修复能力的植物。结果表明：TCIPP具有一定的植物毒性效应,能够抑制4种植物的生长发育,但仅黑麦草的生物量显著降低,其他3种植物的生物量减少不显著。TCIPP易于从植物根部向地上部迁移,其在4种植物组织中的浓度分布均表现为叶>根>茎。4种植物中,苕子叶组织中TCIPP的浓度为15.0 mg/kg,每盆土壤可积累TCIPP 34.9 mg。苕子和紫花苜蓿对土壤中TCIPP的吸收、积累和转运效率较高,其地上部富集系数分别为1.39和1.50,转运系数分别为2.61和3.24。4种植物对TCIPP污染土壤均有较好的修复能力,对土壤中...     

重金属污染土壤植物修复强化技术研究进展

针对重金属污染土壤植物修复技术存在的限制性问题,文章综述了目前植物修复强化技术的研究进展,探讨如何通过采取物理、化学、生物技术及农艺措施等方法提高修复植物的生物量和重金属积累量。重点阐述了基因工程技术、化学诱导技术、微生物技术、蚯蚓强化修复及农艺措施强化植物修复的作用机制及应用效果,并展望了今后的研究方向。     

Phytoremediation for phenanthrene and pyrene contaminated soils

Phytoremediation of soil contaminated with phenanthrene and pyrene was investigated using twelve plant species. Plant uptake nd accumulation of these chemicals were evaluated. At the end of the experiment(45 d), the remaining respective concentrations of soil henanthrene and pyrene in spiked vegetated soils, with initial phenanthrene of 133.3 mg/kg and pyrene of 171.5 mg/kg, were 8.71-16.4 nd 44.9-65.0 mg/kg, generally 4.7%-49.4% and 7.1%-35.9% lower than their concentrations in the non-vegetated soils. The loss f phenanthrene and pyrene in vegetated spiked soils were 88.2%-93.0% and 62.3%-73.8% of the added amounts of these ontaminants, respectively. Although plant uptake and accumulation of these compounds were evident, and root concentrations and RCFs(root concentration factors; defined as the ratio of PAH concentrations in roots and in the soils on a dry weight basis) of these compounds ignificantly positively correlated to root lipid contents, plant uptake and accumulation only accounted for less than 0.01% and 0.23% of the nhanced loss of these chemicals in vegetated versus non-vegetated soils. In contrast, plant-promoted microbial biodegradation was the ominant mechanism of the phytoremediation for soil phenanthrene and pyrene contamination. Results from this study suggested a easibility of the establishment of phytoremediation for soil PAH contamination.     

Root-associated (rhizosphere and endosphere) microbiomes of the Miscanthus sinensis and their response to the heavy metal contamination

The plant root-associated microbiomes, including both the rhizosphere and the root endosphere microbial community, are considered as a critical extension of the plant genome. Comparing to the well-studied rhizosphere microbiome, the understanding of the root endophytic microbiome is still in its infancy. Miscanthus sinensis is a pioneering plant that could thrive on metal contaminated lands and holds the potential for phytoremediation applications. Characterizing its root-associated microbiome, especially the root endophytic microbiome, could provide pivotal knowledge for phytoremediation of mine tailings. In the current study, M. sinensis residing in two Pb/Zn tailings and one uncontaminated site were collected. The results demonstrated that the metal contaminant fractions exposed strong impacts on the microbial community structures. Their influences on the microbial community, however, gradually decreases from the bulk soil through the rhizosphere soil and finally to the endosphere, which resulting in distinct root endophytic microbial community structures compared to both the bulk and rhizosphere soil. Diverse members affiliated with the order Rhizobiales was identified as the core microbiome residing in the root of M. sinensis. In addition, enrichment of plant-growth promoting functions within the root endosphere were predicted, suggesting the root endophytes may provide critical services to the host plant. The current study provides new insights into taxonomy and potential functions of the root-associated microbiomes of the pioneer plant, M. sinensis, which may facilitate future phytoremediation practices.     

Rhizobacteria helps to explain the enhanced efficiency of phytoextraction strengthened by Streptomyces pactum

The ultimate purpose of phytoextraction is not only to remove heavy metals from soil but also to improve soil quality. Here, we evaluated how the joint effect of Streptomyces pactum (strain Act12) and inorganic (Hoagland's solution) and organic (humic acid and peat) nutrients affected the phytoextraction practice of cadmium (Cd) and zinc (Zn) by potherb mustard, and the microbial community composition within rhizosphere was also investigated. The results indicated that the nutrients exerted synergistically with Act12, all increasing the plant biomass and Cd/Zn uptakes. The inoculation of Act12 alone significantly increased dehydrogenase activity of rhizosphere soil (P < 0.05), while urease and alkaline phosphatase activities varied in different dosage of Act12. Combined application of microbial strain with nutrients increased enzymatic activities with the elevated dosage of Act12. 16S ribosomal RNA high-throughput sequencing analysis revealed that Act12 inoculation reduced the diversity of rhizosphere bacteria. The Act12 and nutrients did not change dominant phyla i.e., Proteobacteria, Bacteroidetes, Gemmatimonadetes, Actinobacteria and Acidobacteria, but their relative abundance differed among the treatments with: Peat > Act12 > Humic acid > Hoagland's solution. Comparatively, Sphingomonas replaced Thiobacillus as dominant genus after Act12 application. The increase in the Sphingomonas and Flavisolibacter abundances under Act12 and nutrients treatments gave rise to growth-promoting effect on plant. Our results revealed the important role for rhizosphere microbiota in mediating soil biochemical traits and plant growth, and our approach charted a path toward the development of Act12 combined with soil nutrients to enhance soil quality and phytoextraction efficiency in Cd/Zn-contaminated soils.