镉、砷复合污染土壤钝化修复研究进展

镉、砷复合污染土壤给农田生产和农产品食用安全构成严重威胁.由于镉、砷赋存形态的差异,同步治理难度较大.概述了土壤镉、砷复合污染现状及原位钝化修复难点,着重介绍了当前钝化处理过程中常用的无机和有机钝化材料,多角度探讨了钝化材料多元组配和材料改性的钝化效果及机理,对不同钝化材料的修复成本进行简要的成本效益分析,为镉、砷复合...     

镉砷污染土壤修复技术的文献计量分析

为了解国内土壤镉砷污染修复技术研究现状和未来发展趋势,采用文献计量方法和可视化软件Citespace,结合关键词检索统计方法,使用CNKI全文数据库,检索1999—2019年土壤镉(Cd)和砷(As)污染修复技术相关论文15 301篇,并绘制了网络知识图谱。结果表明：1999—2012年为镉砷污染土壤修复技术文章低发期,2013—2015年发文量跌宕增长;2016—2019年我国镉砷污染土壤修复技术步入了快速发展阶段;在我国土壤镉砷修复领域研究中,植物修复是热点修复手段之一;从研究机构的分布来看,南北方有较大差异,南方地区的发文量大于北方地区。在此基础上,对未来镉砷污染土壤修复技术和发展方向进行了预测分析。可以看出,我国应不断发展多手段结合的联合修复技术,做好土壤镉砷污染修复预警与风险防控仍是未来的工作重点。以上分析结果可为镉砷污染土壤的修复提供借鉴和参考。     

砷污染土壤微生物修复机制及其研究进展

土壤砷污染是一个全球性问题。越来越多的研究表明,自然界中的微生物在砷的迁移转化过程中发挥了重要作用。微生物修复是目前研究的热点,也是治理砷污染土壤的主要手段之一。综述了土壤中砷污染现状及其赋存形式,重点分析讨论了砷污染土壤的微生物修复机制以及提高微生物修复效率的方法。土壤砷污染修复是一项复杂的系统工程,单一的修复技术很难实现显著的效果。只有建立在以微生物修复为主的基础上,辅之以物理化学、植物及农业生态等措施,才能大大提高微生物修复效率。总结了近年来国内外微生物修复砷污染土壤技术的研究进展,以期为深入研究微生物代谢砷的机制及其在砷污染治理中的应用提供参考。     

利用电动技术强化有机污染土壤原位修复研究

电动修复技术是近几年发展起来的一种新型土壤修复技术，由于其处理的高效性受到了越来越多的关注。本文介绍了利用电动技术强化土壤有机污染物原位修复的原理及其最新进展。电动强化有机物污染修复的基本原理是利用电动效应对有机物的迁移作用或者强化生物修复过程（注入营养物、电子受体和活性微生物等）达到去除污染物的目的。研究表明，该技术不破坏生态环境，安装操作简单成本低廉，具有广泛的应用前景，其中电动强化原位生物修复和能够适应于各种不同成分污染（如有机物重金属复合污染）的多技术联合是今后电动技术发展的重要方向。     

重金属污染土壤原位钝化修复材料的最新研究进展

土壤环境关系到人们的身体健康,重金属污染土壤的修复一直以来是全球环境领域关注的焦点和研究的热点。重金属原位钝化修复技术是一种有前景的解决方案。其中,钝化材料是关键。着重介绍了不同类型重金属污染土壤原位钝化修复材料的修复原理、修复效果及应用情况,简要分析了修复材料的成本和效益,为重金属污染土壤原位钝化修复研究提供相关信息。     

硫化钠对土壤中铅镉的固定效果简

研究了硫化钠用于固定土壤中铅镉的可行性,考察了硫化钠用量及土壤pH、有机质对固定过程中土壤铅、镉赋存形态及固定效果的影响。结果表明,添加硫化钠可改变土壤中铅镉的形态分布,明显降低可交换态铅镉的含量。条件适当时,铅镉可交换态下降值分别为63%和73%。硫化钠在固定铅的过程中,固定效率对土壤pH、有机质含量的变化较为敏感,在有机质含量较低或酸性土壤中,硫化钠对铅固定效率较高;相对于铅,有机质含量和pH变化对镉的固定效率影响不是很大。     

FeMnCa-LDHs材料对不同程度砷镉复合污染土壤的钝化修复

针对土壤砷镉复合污染同时修复较为困难的问题,制备了新型FeMnCa-LDHs材料以实现对土壤中As、Cd的同时钝化。通过土壤培养实验和小白菜盆栽实验,研究了在不同污染水平下FeMnCa-LDHs材料施用量对土壤As、Cd的形态转化及对小白菜各部位中As、Cd质量分数的影响,并分析了两者的相关性。结果表明,在高污染水平下施用1.0%的FeMnCa-LDHs材料,可使弱酸提取态As和弱酸提取态Cd的质量分数分别下降12.1%和28.9%,As和Cd由弱酸提取态向更稳定的形态转化;材料对As的吸附作用及对土壤pH的提高是其同时钝化As和Cd的主要原因。在高污染水平下,0.5%的材料施用量可使小白菜地上部分中As和Cd的质量分数分别减少61.2%和53.0%。相关性分析结果表明,小白菜各部位中As和Cd的质量分数与土壤中弱酸提取态As和弱酸提取态Cd的质量分数呈显著正相关,与残渣态As和残渣态Cd的质量分数呈显著负相关,这说明FeMnCa-LDHs材料通过改变土壤中As、Cd的形态分布降低了As、Cd的生物有效性。本研究可为土壤As、Cd复合污染提供参考。     

5种钝化剂对镉砷污染稻田的田间修复效果对比

为选取费效比高的镉砷复合污染稻田土壤修复材料,比较了黏土矿物和调理剂不同投加组合对稻田土壤中镉砷的田间修复效果,并且针对种植水稻进行了修复效果的验证;研究了修复前后稻田土壤镉砷的有效形态变化、镉砷的形态分布变化、土壤理化性质变化、成熟期水稻产量和水稻各部分镉砷的含量。结果表明,修复100 d后,不同修复材料的二乙烯三胺五乙酸提取态Cd浓度与空白对照组相比均有明显下降;各修复材料均能提高土壤中Cd的残余态(RS)和As的有机结合态(OM)。修复材料处理后,土壤pH均有所提升,其他理化性质初期虽有所变化,但最终会恢复到空白对照组的水平附近;除1 kg·m~(-2)的膨润土处理外,其他材料处理后水稻干谷产量均有所提升;农田调理剂处理后水稻的可食用部分Cd含量最低,修复率达到72.0%。水稻的可食用部分As含量无显著差异,籽粒中Cd和As平均含量符合食用标准。调理剂在田间修复镉砷复合污染稻田土壤中有明显优势,黏土矿物仅适用于镉污染农稻田土壤的修复。     

污染土壤的物理/化学修复

将土壤污染物分为非卤代VOCs、卤代VOCs、非卤代SVOCs、无机物等8大类型,并在分析污染土壤原位修复和异位修复两种方式不同特点的基础上,根据各种修复技术的不同作用原理,较为全面地介绍了目前国内外各种物理/化学修复的技术原理、适用性、局限性、实施时间及处理成本等,具体包括化学淋洗、蒸汽抽提、强化破裂、空气喷射、可渗透反应墙、固化/稳定化、电动学、物理分离、热解吸、玻璃化等修复技术.针对几种常见的土壤污染类型,列举了一些可行的组合修复工艺.     

含铁材料对污染水稻土中砷的稳定化效果

通过化学实验方法,向砷污染水稻土中添加4种含铁材料(FeCl3、FeCl2、Fe0和Fe2O3),分析稳定后土壤中pH、砷形态及砷毒性浸出量的变化,研究4种含铁材料对污染水稻土中砷的稳定化效果。结果表明,FeCl3和FeCl2处理降低了土壤pH,Fe0和Fe2O3处理对土壤pH影响不大。4种含铁材料均明显降低了土壤中易溶态砷(WE-As)和毒性浸出砷含量。在最大添加量为8.00 g/kg时,FeCl3、FeCl2、Fe0和Fe2O3分别使易溶态砷比对照降低了86.4%、63.6%、77.3%和36.4%,使毒性浸出砷比对照降低了96.3%、88.9%、70.4%和30.4%。4种含铁材料均对水稻土壤中砷具有较好的稳定化效果,且能力大小依次为:FeCl3FeCl2、Fe0Fe2O3。Fe0和Fe2O3处理使WE-As、铝型砷(Al-As)、铁型砷(Fe-As)向钙型砷(Ca-As)和残渣态砷(RS-As)转化;FeCl3处理使土壤WE-As、Al-As向Fe-As、Ca-As和RS-As转化;FeCl2处理使土壤WE-As、Ca-As向Al-As、Fe-As转化,对RS-As影响不明显。说明Fe0固砷的机理与Fe2O3相似,与FeCl3有一定差异,与FeCl2的差异可能更大。     

Inactivation of cadmium in contaminated soils using synthetic zeolites

The addition of synthetic zeolite pellets to soils contaminated with cadmium significantly reduced the concentrations of cadmium in the roots and shoots of a range of crop plants. Use of synthetic foyazite group zeolites types 4A and 13X, at application rates of 1% by soil weight, caused reductions in cadmium concentrations of up to 86% in leaves of lettuce grown in pots, compared to controls with no added zeolites. The potential of these substances to reduce cadmium entry into the food chain, and as a clean up method, is noted.     

Effects of oxalate and phosphate on the release of arsenic from contaminated soils and arsenic accumulation in wheat

Oxalate is exuded by plants in the rhizosphere and plays an important role in the soil/root interactions. Phosphate fertilizer is widely used all over the world and may influence the behavior of arsenic (As) in soils. In this study oxalate and phosphate were used as extractants to investigate their effects on the release of As from three As-contaminated soils and the chemical speciation of As. Concentrations of arsenite (As(III)) and arsenate (As(V)) released progressively increased by increasing the concentrations of oxalate or phosphate. The released As(V) content was higher than that of As(III) and the differences between As(V) and As(III) released by oxalate was more obvious than by phosphate. Greenhouse experiment was conducted to evaluate the effects of oxalate and phosphate on As uptake by wheat (Triticum vulgare L.). Addition of oxalate or phosphate resulted in the increase of As accumulation in both wheat root and shoot and the effect of phosphate was more obvious than that of oxalate.     

Biosurfactant technology for remediation of cadmium and lead contaminated soils

This research focuses on column experiments conducted to evaluate the potential of environmentally compatible rhamnolipid biosurfactant produced by Pseudomonas aeruginosa strain BS2 to remove heavy metals (Cd and Pb) from artificially contaminated soil. Results have shown that di-rhamnolipid removes not only the leachable or available fraction of Cd and Pb but also the bound metals as compared to tap water which removed the mobile fraction only. Washing of contaminated soil with tap water revealed that approximately 2.7% of Cd and 9.8% of Pb in contaminated soil was in freely available or weakly bound forms whereas washing with rhamnolipid removed 92% of Cd and 88% of Pb after 36 h of leaching. This indicated that di-rhamnolipid selectively favours mobilization of metals in the order of Cd>Pb. Biosurfactant specificity observed towards specific metal will help in preferential elution of specific contaminant using di-rhamnolipid. It was further observed that pH of the leachates collected from heavy metal contaminated soil column treated with di-rhamnolipid solution was low (6.60-6.78) as compared to that of leachates from heavy metal contaminated soil column treated with tap water (pH 6.90-7.25), which showed high dissolution of metal species from the contaminated soil and effective leaching of metals with treatment with biosurfactant. The microbial population of the contaminated soil was increased after removal of metals by biosurfactant indicating the decrease of toxicity of metals to soil microflora. This study shows that biosurfactant technology can be an effective and nondestructive method for bioremediation of cadmium and lead contaminated soil.     

生物炭对Cd污染土壤的修复效果与机理

通过修复培养实验和BCR连续提取实验研究牛粪生物炭（DM）和水稻秸秆生物炭（RS）对2种镉污染土壤的修复效果、影响因素及修复后的Cd的形态分布,探讨可能存在的修复机理。经56 d修复后,与CK相比,5%添加量的牛粪生物炭（DM5%）和水稻秸秆生物炭（RS5%）使TCLP提取态Cd在S1土壤中分别降低了15%和18%,在S2土壤中分别降低了5%和6%。但生物炭添加量为1%时对S2土壤中Cd无显著修复效果。DM5%和RS5%处理使Cd的酸可溶态在S1土壤中降低8.66%和9.25%,在S2土壤中降低7.86%和13.4%,相应的残渣态在S1土壤中升高8.30%和10.54%,在S2土壤中升高8.67%和14.92%。同时,DM5%和RS5%处理使土壤pH提高了7.69%~13.13%,TCLP提取态P增高了0.046~0.39 mg·g-1。结果表明,添加量为5%的牛粪生物炭和秸秆生物炭可有效修复Cd污染土壤。     

Feasibility of phytoextraction to remediate cadmium and zinc contaminated soils

A Cd and Zn contaminated soil was mixed and equilibrated with an uncontaminated, but otherwise similar soil to establish a gradient in soil contamination levels. Growth of Thlaspi caerulescens (Ganges ecotype) significantly decreased the metal concentrations in soil solution. Plant uptake of Cd and Zn exceeded the decrease of the soluble metal concentrations by several orders of magnitude. Hence, desorption of metals must have occurred to maintain the soil solution concentrations. A coupled regression model was developed to describe the transfer of metals from soil to solution and plant shoots. This model was applied to estimate the phytoextraction duration required to decrease the soil Cd concentration from 10 to 0.5 mg kg⁻¹. A biomass production of 1 and 5 t dm ha⁻¹ yr⁻¹ yields a duration of 42 and 11 yr, respectively. Successful phytoextraction operations based on T. caerulescens require an increased biomass production.     

The impact of sequestration on the bioaccessibility of arsenic in long-term contaminated soils

Arsenic (As) contamination of soil poses a potential threat to human health, particularly for small children, through the incidental ingestion of soil from hand-to-mouth activity. In this study, we examined the relationship between As bioaccessibility using the simplified bioaccessibility extraction test (SBET) and the soil fractions that contribute to bioaccessible As in 12 long-term contaminated soils. Sequential fractionation of soils prior to As bioaccessibility assessment found that As was primarily associated with the specifically sorbed (3-26%), amorphous and poorly crystalline (12-82%), and the well crystalline (3-25%) oxyhydroxide Fe/Al phases with proportions varying depending on the mode of As input. Arsenic bioaccessibility in these soils ranged from less than 1% in the gossan soil to 48% in railway corridor soils. Soil fractions contributing to As bioaccessibility were found to be from the non-specifically (<1-11%), the specifically (<1-29%) sorbed and the amorphous and poorly-crystalline (30-93%) oxyhydroxide Fe/Al fractions. Significant correlations (p<0.05) were found between the As bioaccessible fraction and the amorphous and poorly-crystalline oxyhydroxide Fe/Al fractions indicating that this fraction is a key factor influencing As bioaccessibility in many anthropogenically contaminated soils.     

Effect of cadmium on nodulation and N2-fixation of soybean in contaminated soils

The effects of cadmium stress on nodulation, N2-fixation capabilities of the root nodule, the change in ultrastructure of the root nodule, soybean growth, and the distribution of cadmium in plants were studied. The results obtained show that the nodulation of soybean roots was greatly inhibited by the addition of Cd, especially at the addition level of 10 and 20 mg kg(-1) soil. The inhibition of plant growth, especially the root growth, increased as the cadmium concentration increased, with deleterious effects observed for the roots. The weight ratio of soybean root/leaf decreased as the Cd concentration increased, which might explain the reason for nodulation decreases. The results also indicate that N2-fixation of root nodule was stimulated to some extent at the low levels of Cd addition, but decreased sharply with further increase of the Cd concentration. High Cd levels were also associated with changes in the ultrastructure of root nodule, in which the effective N2-fixing area was reduced and the N2-fixing cells in the area also reduced. In addition, the results also reveal that the content of Cd in different parts of the plants was as follows: roots > stems > seeds, indicating that the accumulation of Cd by roots is much larger than that by any other part of the soybean plant, and might cause deleterious effects to root systems.     

砷污染土壤柠檬酸萃取修复技术研究

伴随着砷工业的发展,含砷化学品引发的重大环境污染事故时有发生。一般砷污染事件发生后,土壤是其最直接的受害者,有必要寻找一种快速且行之有效的方法对砷污染土壤进行控制修复。针对此问题,通过实验探讨了柠檬酸萃取修复砷污染土壤的效果,研究了柠檬酸浓度、液土比、萃取时间及土壤共存离子对柠檬酸萃取砷的效果的影响,为砷污染土壤的治理提供依据。结果表明,柠檬酸是一种高效的砷萃取剂;随着柠檬酸浓度、液土比、萃取时间的增加,砷的萃取率均有所升高;当柠檬酸摩尔浓度为0.25 mol/L、液土比为20 mL/g、萃取时间为21 h时,柠檬酸对砷的萃取率达到最高值(70.58%);土壤中共存的PO43-、Zn2+、Fe2+,由于其竞争作用,能使柠檬酸对砷的萃取率降低。