铜尾矿复垦后土壤微生物活性及其群落功能多样性研究

对安徽铜陵五公里尾矿区三叶草复垦后的土壤微生物活性和群落的功能多样性研究表明,复垦后每克土壤微生物细菌数已达2.3×107个,并存在一定量耐Cu2 、Cd2 、Zn2 、Cr6 、Pb2 、Ni2 的菌株,但种类少,主要为芽孢杆菌属、假单胞菌属和短杆菌属。BIOLOG测试结果显示,铜镉重金属离子的复合污染使土壤微生物群落丰富度降低;外源耐铜镉微生物菌剂的添加使尾矿区土壤微生物群落代谢剖面(AWCD)变化明显,提高微生物对单一碳源底物的利用能力,增加利用不同碳底物的微生物数量,减轻了重金属污染引起的土壤微生物群落功能多样性的下降,为尾矿区生境加速恢复提供一条有效途径。     

土壤中镉铜复合污染对水稻生长效应影响

本文通过盆栽试验研究土壤中镉铜复合污染对水稻生长效应的影响,并探讨了有效态铜、镉的提取剂。结果表明,2.5％醋酸可作为酸性水稻土有效态铜、镉的提取剂,土壤含镉5mg/kg对铜的水稻产量效应未有影响,但糙米含镉量超标。     

有机物质添加量对污染土壤铜形态及活性的影响

分析了泥炭和堆肥两种有机物质的添加量水平对冶炼厂附近污染土壤中铜形态及其活性的影响。结果表明, 添加土重２ ． ５ ％ 有机物质就对土壤铜化学形态与活性产生显著的影响, 使氧化锰结合态和松结合有机态铜等向紧结合有机态铜转化, 使土壤化学活性铜 （２ ． ５ ％ 醋酸提取） 降低约２０ ％ ; 添加量增加到５ ． ０ ％ , 控制作用有明显加强的趋势; 添加量再增至１０ ． ０ ％ , 单位添加量有机物质的控制作用明显减弱。     

植物群落对铜尾矿废弃地土壤微生物量和酶活性的影响

以铜尾矿废弃地为对象,研究了铜尾矿废弃地上植物群落发展与表层尾矿微生物量C、N和脱氢酶、过氧化氢碱性磷酸酶和脲酶活性的变化,探讨了植物群落-微生物量C、N_土壤酶活性之间的相互关系.结果表明,随着植物群落的发展,铜尾矿废弃地表层尾矿微生物量和酶活性在不断增加;铜官山老尾矿废弃地白茅群落下表层尾矿(TBM)微生物量和酶活性与杨山冲尾矿废弃地及铜官山新尾矿废弃地表层尾矿微生物量和酶活性存在显著差异性(p<0.05).相关分析表明铜尾矿废弃地表层尾矿微生物量C、N与土壤有机质、总氮之间呈显著正相关(P<0.01);脱氧酶、碱性磷酸酶及脲酶与微生物量C、微生物量N、土壤有机质、总氮之问呈显著正相关(P<0.01),但过氧化氢酶与微生物量C、微生物量N、土壤有机质、总氮之间呈显著负相关(P<0.01).     

蔬菜对土壤镉铜锌富集能力的研究

调查了福建部分污染严重地区不同蔬菜对镉、锌、铜的富集能力。结果表明蔬菜对镉的平均富集系数为0.017,锌的平均富集系数为0.116.铜的平均富集系数为0.014。蔬菜对镉的富集系数的品种间差异最大,达315倍,远高于锌和铜的富集系数的品种间差异。茭白、豇豆和莲藕对镉的富集能力较低,可作为镉污染土壤优先选种的蔬菜品种,而青包菜、白包菜、芥菜、空心菜、芋头等对镉的富集系数较高,不宜在镉污染土壤上栽培。     

生物炭对重污染土壤镉形态及油菜吸收镉的影响

为了解不同种类和用量的生物炭对土壤镉形态及油菜吸收镉的影响,通过室外盆栽试验,以湖南某冶炼区周边重镉污染土壤为供试土壤,湘油27号为供试作物,于油菜移栽前7d分别添加w为0.1％和1％的竹炭和柠条炭,分析土壤镉形态和成熟期油菜各器官镉含量.结果表明,添加生物炭能降低土壤镉的有效性和油菜各器官中镉含量.柠条炭降低油菜吸收累积镉的效果比竹炭更明显,且随着生物炭量的增加阻控效果更明显.相比于对照组,施用生物炭后土壤中w(可交换态镉)最大可降低16.64％;油菜根部、茎秆、油荚和籽粒w(镉)最大可分别降低34.06％ 、39.74％、33.15％和49.81％.综合结果表明,添加w=1％柠条炭处理组处理效果最佳.     

重金属复合污染土壤中耐铅镉微生物的筛选及鉴定

为获得复合重金属高耐性微生物资源菌株,采集广西桂西北尾矿区重金属污染的土壤样品,采用改良的马丁氏培养基分离和筛选既耐铅又耐镉的高耐性微生物.结果获得了一株耐铅浓度为1 200 mg/L、镉浓度为120 mg/L的铅镉复合耐性真菌——菌株K-3.该菌株(K-3)最适生长环境为温度30℃、p H值7.0、盐浓度3%.通过形态结合分子生物学鉴定得知,K-3菌株与已知分类地位的标准菌株Uncultured Westerdykella的18S rDNA序列一致性为99%.本研究获得的铅镉复合耐性真菌——菌株K-3是重金属铅和镉的最强双耐真菌之一,可为微生物或微生物联合植物修复重金属污染土壤提供重要的微生物种质资源.(图8表3参39)     

不同微生物菌剂对当归苗生长及根际土微生物和养分的影响

通过当归拌种育苗试验研究4种微生物菌剂对当归新茬地和连作地育苗质量和品质的影响,通过测定根际土养分和可培养微生物类群数探讨添加外源微生物菌剂对当归苗根际土微生物和养分代谢功能的调节作用.结果显示:4种微生物菌剂处理在新茬地和连作地育苗条件下,均显著提高一等苗并降低废弃苗;其中复合真菌菌剂(PO+BB)处理在新茬地和连作地对有效苗数量的提高效果最好,较对照(CK)处理分别提高了6.6%和26.8%;添加外源微生物菌剂均极显著地改变根际土细菌、真菌、放线菌、氨化细菌和固氮菌等可培养微生物的类群数量(P0.001),同时也显著影响了有机质、有效钾和有效磷在根际土的积累和转化利用(P0.01).新茬地和连作地根际土微生物与养分的相关分析结果显示,连作地育苗显著改变了根际土微生物与养分的相关关系;而外源微生物菌剂处理条件下,根际土微生物与养分的相关分析结果显示,不同微生物菌剂不仅改变某类微生物与根际土养分的相关关系,而且与其他养分的积累和转化利用存在一定的协同效应.本研究表明,添加外源微生物菌剂通过影响根际微生物类群数量和功能改善了根际土养分的含量和植物的吸收利用能力,进而提高了当归苗的品质,因此在当归栽培过程中具有较好的应用前景.     

钒钛磁铁矿尾矿土壤解钾细菌的多样性及镉对其解钾能力的影响

解钾菌能分解钾长石、磷灰石等不溶硅铝酸盐无机矿物,使土壤难溶性钾转化为可溶性养分,促进作物生长发育,而钒钛磁铁矿尾矿土壤中解钾细菌的多样性及重金属镉对细菌解钾能力是否有影响尚不清楚.从攀枝花钒钛磁铁尾矿土壤中分离纯化细菌资源,通过对细菌解钾能力的定性筛选和定量测定获得高效解钾细菌,利用16S rRNA基因相似性与系统发育分析明确解钾细菌的进化地位,研究不同浓度镉胁迫下高效解钾细菌解钾效率的变化规律,揭示镉对细菌解钾能力的影响.结果显示,通过钾长石粉筛选培养基点接细菌,从136株钒钛磁铁尾矿土壤细菌中筛选出7株解钾细菌,包括根瘤菌(Rhizobium)3株、芽孢杆菌(Bacillus)2株、苍白杆菌(Ochrobactrum)1株、产碱杆菌(Advenella)1株,其在钾长石粉液体培养基中的解钾量为18.63-31.32 mg/L.其中,产碱杆菌KT106解钾能力最强,在培养第6天时解钾量最大;KT106对镉表现出一定的耐受性,其在不同浓度的镉胁迫下解钾效率降低.本研究表明,攀枝花钒钛磁铁尾矿土中仅有5%细菌具有解钾能力,较高浓度的重金属镉对细菌解钾能力有抑制作用,结果可为解钾促生细菌强化植物修复重金属污染土壤提供科学支撑.     

一株耐铅镉真菌Q7对香根草吸收累积重金属的效应

采用双因素完全随机区组试验探讨耐性真菌联合香根草修复铅(Pb)、镉(Cd)复合污染土壤效应.其中A因素为加菌量,设置0、1、3、5 g共4个水平,菌株代号Q7.B因素为铅镉添加量,设置Cd0Pb0、Cd10Pb400、Cd20Pb600、Cd30Pb800、Cd50Pb1200、Cd80Pb1800(单位为mg/kg)6种不同铅镉浓度水平.结果表明,添加耐性真菌可显著提高香根草生物量,1、3、5 g加菌量处理可分别使香根草总干重增加量达到41.9%、74.9%、71.7%.耐性真菌可促进香根草地上部与地下部对铅镉的富集,Cd~(2+)80 mg/kg、Pb~(2+)1 800 mg/kg处理下,1、3、5 g加菌量处理香根草对铅富集量比不加菌处理,地上部分别升高了120.6%、265.4%、242.9%,地下部分别升高了110.3%、278.2%、266.2%;对镉而言,地上部镉含量分别升高了113.2%、238.3%、217.3%,地下部分别升高了103.1%、298.8%、274.4%.加菌可强化香根草对铅镉污染土壤的修复效果,且3 g加菌量强化香根草修复效果要优于1 g和5 g加菌量处理.综上,将耐性真菌与重金属富集植物香根草在不同铅镉复合污染浓度下构建联合修复体系,显示了真菌对香根草修复铅镉污染土壤的显著强化效应.     

稀土尾矿区土壤重金属污染与优势植物累积特征

矿山废弃地不仅占用大量土地,而且还是严重的污染源,因此,矿山废弃地的生态恢复己成为一项紧迫而重要的研究课题。对广东省河源市和平县下车镇内的稀土矿区土壤的重金属污染情况进行调查,并对该区优势植物对重金属的富集特征进行分析,以期对稀土尾矿区的生态系统的恢复和重建提供理论依据。主要研究的3种植物分别是：马唐草（Digitaria sanguinalis）,香根草（Vetiveria zizanioides）,望江南（Cassia occidentalis）。采用原子吸收分光光度法测定稀土矿区废弃地土壤和植被中Mn、Pb、Zn的含量,并计算优势植物对重金属的生物富集系数BAC（Biological Accumulating Coefficient）和生物转移系数BTC（Biological Transfer Coefficient）。结果表明：研究区域的土壤中重金属含量Mn、Pb、Zn的平均含量均超出广东省土壤背景值和中国土壤背景值,土壤受Mn污染最严重,其次是Pb、Zn的污染。3种草本植物对于Pb的BAC和BTC均小于1,说明这3种植物对Pb的富集和运输能力都很弱。香根草对于Mn和Zn的BAC分别为0.9和0.4,小于1,BTC分别为3.7和1.1,大于1,说明香根草对Mn和Zn的富集能力不强,但吸收后的运输能力很强。马唐草和望江南2种植物对于Mn和Zn的BAC和BTC均大于1,说明它们对重金属Mn和Zn具有较强的吸收和转移能力,是Mn和Zn的超富集植物。马唐草覆盖率高,抗病虫能力强,可作为该矿区生态恢复的先锋植物,望江南可以间作种植。     

An Investigation Into the Mechanism by Which Synthetic Zeolites Reduce Labile Metal Concentrations in Soils

The addition of synthetic zeolites and similar materials to metal contaminated soils has been shown to reduce soil phytotoxicity and to improve the quality of plant growth on such amended soils. To gain an understanding of the mechanism by which the phytotoxicity of contaminated soils is reduced when treated with synthetic zeolites, sequential extraction procedures and soil solution techniques have been used to identify changes associated with metal speciation in amended soils. Sequential extraction data and changes in soil solution composition are presented for three different contaminated soils, amended with three synthetic zeolites (P, 4A and Y) at concentrations of 0.5%, 1% and 5% w/w, or lime at 1%. The soils were collected from the site of a metal refinery, an old lead zinc mine spoil tip and from a field which had been treated with sewage sludge. After incubation of the zeolite treated soils for between one and three months, results showed a reduction in the metal content of the ammonium acetate fraction between 42% and 70%, depending on soil, zeolite and rate of addition, compared with the unamended soils. In addition, soil solution experiments indicated that synthetic zeolite amendments were more efficient at reducing metal content than comparable lime treatment. The mechanism by which synthetic zeolites reduce metal bioavailability in contaminated soils is discussed and compared to other amendments.     

不同来源重金属在土壤中的形态分布差异

试验表明：不同来源的Ｐｂ、Ｚｎ和Ｃｄ复合污染物在土壤中的形态分布有明显的差异，在废矿水和尾矿砂污染的土壤中，Ｐｂ、Ｚｎ和Ｃｄ主要以残渣态存在，而添加土壤中的Ｐｂ主要以弱专性吸附态和有机结合态存在，Ｚｎ和Ｃｄ主要以交换态存在，大豆苗对添加土壤中Ｐｂ、Ｚｎ和Ｃｄ的富集能力较强，而对废矿水污染和尾矿砂污染土壤中Ｐｂ、Ｚｎ和Ｃｄ的富集能力相对较弱。     

A feasibility study on bioelectrokinetics for the removal of heavy metals from tailing soil

The combination of bioremediation and electrokinetics, termed bioelectrokinetics, has been studied constantly to enhance the removal of organic and inorganic contaminants from soil. The use of the bioleaching process originating from Fe- and/or S-oxidizing bacteria may be a feasible technology for the remediation of heavy metal-contaminated soils. In this study, the bioleaching process driven by injection of S-oxidizing bacteria, Acidithiobacillus thiooxidans, was evaluated as a pre-treatment step. The bioleaching process was sequentially integrated with the electrokinetic soil process, and the final removal efficiency of the combined process was compared with those of individual processes. Tailing soil, heavily contaminated with Cd, Cu, Pb, Zn, Co, and As, was collected from an abandoned mine area in Korea. The results of geochemical studies supported that this tailing soil contains the reduced forms of sulfur that can be an energy source for A. thiooxidans. From the result of the combined process, we could conclude that the bioleaching process might be a good pre-treatment step to mobilize heavy metals in tailing soil. Additionally, the electrokinetic process can be an effective technology for the removal of heavy metals from tailing soil. For the sake of generalizing the proposed bioelectrokinetic process, however, the site-specific differences in soil should be taken into account in future studies.     

Preface

The combination of bioremediation and electrokinetics, termed bioelectrokinetics, has been studied constantly to enhance the removal of organic and inorganic contaminants from soil. The use of the bioleaching process originating from Fe- and/or S-oxidizing bacteria may be a feasible technology for the remediation of heavy metal–contaminated soils. In this study, the bioleaching process driven by injection of S-oxidizing bacteria, Acidithiobacillus thiooxidans, was evaluated as a pre-treatment step. The bioleaching process was sequentially integrated with the electrokinetic soil process, and the final removal efficiency of the combined process was compared with those of individual processes. Tailing soil, heavily contaminated with Cd, Cu, Pb, Zn, Co, and As, was collected from an abandoned mine area in Korea. The results of geochemical studies supported that this tailing soil contains the reduced forms of sulfur that can be an energy source for A. thiooxidans. From the result of the combined process, we could conclude that the bioleaching process might be a good pre-treatment step to mobilize heavy metals in tailing soil. Additionally, the electrokinetic process can be an effective technology for the removal of heavy metals from tailing soil. For the sake of generalizing the proposed bioelectrokinetic process, however, the site-specific differences in soil should be taken into account in future studies.     

Microorganisms and physico-chemical properties of soils with different slope-protecting vegetation in Daguang Highway北大核心CSCD

In order to investigate the effect of different slope-protecting vegetation on soil restoration in the highways, we collected soils at depths of 0-10 cm, 10-20 cm, and 20-30 cm from areas planted with Amorpha fruticosa, Periploca sepium, and Paederia scandens for 6-7 years in the Daming road section of the Daguang Highway, in October 2016. The physico-chemical properties and microbial community of the soils were then analyzed. The soil microbial community was analyzed by terminal restriction fragment length polymorphism (T-RFLP). The correlation between the microbial community and the physico-chemical properties of the soils was determined by redundancy analysis (RDA). The results showed that (1) the physico-chemical properties were the best for soils with Paederia scandens; the nutrient content, water holding capacity, and porosity of the soils with the three types of slope-protecting vegetation were better in the 0-10 cm layer than in the other layers; (2) the contents of soil aggregates (diameter > 5 mm) were the highest in the 0-10 cm and 10-20 cm layers for the soil with Paederia scandens; (3) the dominant bacteria in the 0-10 cm layer and dominant fungi in the 0-10 cm, 10-20 cm, and 20-30 cm layers were higher in the soils with Pe. sepium and Pa. scandens than in the soil with A. fruticosa; and (4) results of RDA showed that the physical properties of the soils were the main factors that influenced the soil microbial community. The physical properties of the soils were sensitive to the change of soil quality. Soil quality can be improved by appropriate management measures, such as burying litter, which can subsequently improve the ecological environment of soils in sloping regions. © 2018 Science Press. All rights reserved.     

韶关矿产资源开采地区土壤生态系统的微生物生态效应研究

韶关地区大宝山铁多金属矿产资源的开采给环境带来了严重的危害。采选冶产生的废液及固体废弃物堆积的淋滤酸水,携带浸滤出的大量重金属离子排入下游河道,严重影响矿区及酸水流域的生态环境。通过对该铅锌矿区土壤重金属分布、土壤微生物数量与植物重金属积累特征进行采样分析研究,结果表明：铅锌矿区土壤各重金属元素质量分数均高于对照土壤,矿区土壤均受到不同程度的污染;五节芒（Miscanthusfloridulus）植物中的元素质量分数表现为Zn〉Pb〉Cu〉Cd,Zn与土壤元素的相关性最为显著,其次为Pb;与对照土壤相比,矿区土壤微生物总数下降了68．43％-80．32％,各主要生理类群数量均呈下降趋势。矿区土壤生态系统处于不利于有益微生物的繁殖和活动的境地,从而大大削弱了土壤中C、N营养元素循环速率和能量流动。     

Ecological consequences of carbon substrate identity and diversity in a laboratory study

Plants return a wide range of carbon (C) substrates to the soil system. The decomposition rate of these substrates is determined by their chemical nature, yet few studies have examined the relative ecological role of specific substrates (i.e., substrate identity) or mixtures of substrates. Carbon substrate identity and diversity may alter soil chemistry and soil community composition, resulting in changes in belowground ecosystem functions such as decomposition and nutrient transfer, creating feedbacks that may affect plant growth and the aboveground community. A laboratory experiment was set up in which eight C substrates of varying chemical complexity were added to a base soil singly, in pairs, fours, or with all eight together every four days over a 92-day period. After 92 days these soils were analyzed for changes in chemistry, microbial community structure, and components of ecosystem functioning. The identity of the added C substrates significantly affected soil chemistry, microbial basal and substrate-induced respiration, and soil microbial community structure measured by either the catabolic response profile (CRP) technique or phospholipid fatty acid composition. These belowground changes strongly affected the ability of the soil microflora to decompose cellulose paper, probably because of differential effects of the C substrates on soil energy supplies and enzyme activities. The addition of C substrates to soils also reduced plant growth compared to the unamended control soil, but less so in soils amended with a tannin than those amended with other substrates. Carbon substrate diversity effects saturated at low diversity levels, tended to have neutral or negative effects on ecosystem functions, and depended strongly on which C substrates were added. It increased CRP compound use but had little effect on other measures of the soil microbial community. Overall, results showed that the chemical nature of C substrates added to soil, and sometimes their diversity, can affect the soil microbial community and soil chemistry, which subsequently affect other ecosystem processes such as decomposition and plant growth. The identity and diversity of substrates that plants add to soil may therefore have important consequences for both above- and belowground ecosystem functions.     

典型铜尾矿库周边土壤重金属复合污染特征

应用了Hakanson潜在生态风险指数法、相关分析法、主成分分析法对德兴铜矿尾砂库周边土壤Cu、Zn、Ni、Pb、Cr和Cd复合污染特征进行研究,定量确定了铜尾矿库潜在生态风险程度、主要污染因子和潜在生态风险因子。结果表明：铜矿尾矿库周边土壤受到不同程度的重金属污染,该地区平均潜在生态风险污染指数超过600,具有极高的潜在生态风险;各重金属潜在生态风险参数由高至低顺序为Cd、Cu、Pb、Ni、Cr、Zn,其中Cd为主要潜在生态风险因子。进一步通过主成分分析法研究了重金属的污染特性,发现前3个主成分贡献率分别为：65．033％、18．825％、6．243％,第一主成分反映了Zn、Ni、cr的信息,第二主成分反映了Cu和Cd的信息,第三主成分反映Pb的信息。     

土著微生物原位修复石油污染土壤试验研究

利用当地土著微生物优势菌群,辅以物理和化学的方法,结合当地地质微环境特点,开展了陕北某油井旁的石油污染黄土土壤修复研究。设置两个试验区、一个空白区和一个对照区,在两个试验区中分别加入3%的土著优势菌群制剂,选择优化出的土著菌群经鉴定,主要有：假单胞菌属（Pseudomonas）、微球菌属（Micrococcus）、放线菌属（Actinomayces）、真菌类的青霉属（Penicillium）、曲霉属（Aspergillus）等。试验结果显示：土著优势菌剂一般需要3-7d的延滞期（lag phase）,然后进入对数期（logarithmic phase）;两个试验区土壤中人为添加石油含量分别为1542、1886mg·kg^-1时,经过11-32d原位土著优势微生物菌剂的修复,土壤中的石油污染物降解率可达69.52%-88.11%,而对照区土壤中人为添加的石油含量变化不大,降解率基本在10%以内,说明在自然条件下土壤中石油降解是缓慢的。谷糠黍糠、麦麸两种添加剂对优化菌液的修复效果的作用基本相同。试验过程中对土壤温度、水分、氧和营养物质等影响因素进行了调控,起到了良好的作用。