人工湿地废水生态处理系统的作用机制

人工湿地废水生态处理新技术的高效去污能力基于独特而复杂的作用机制，其中最重要的是湿地基质、大型植物和微生物的高度协同作用。基质在为植物和微生物提供生长介质的同时，也能够通过沉淀、过滤和吸附等作用直接去除污染物。大型湿地植物既是微生物的“固定化载体”，氧气的生产和运输“机器”，同时还能够稳固湿地床表面，起到冬季保温和支撑冰面的作用。微生物是消除污染物的作用者，它能够在去除氮、磷等营养物的同时把有机质作为丰富的能源转化为营养物质和能量。     

人工湿地系统微生物去除污染物的研究进展

人工湿地污水处理系统具有净化效果显著、建设和运行费用低廉、管理简便等优点,近年来越来越受到人们的重视。人工湿地是利用介质、植物和微生物构成的复合系统来处理污水。微生物在人工湿地系统净化污水过程中发挥着重要作用。介绍了人工湿地系统中微生物去除污染物的研究进展,重点讨论了人工湿地对污染物和特殊有机污染物的去除以及系统基质中微生物的种群和活性等内容,并结合我国研究现状展望了该领域的研究前景。人工湿地系统微生物对污染物去除将成为人工湿地生态系统服务功能评价、人工湿地生态系统健康与稳定的诊断的重要组成部分。     

人工湿地中基质与植物对污染物去除效率的影响

针对太湖五里湖富营养化水体,采用中试规模的人工湿地现场实验开展了不同基质、不同植物的污染物去除效果研究。基质采用炉渣和沸石2种,在一个湿地池种植单一植物茭白,另一个湿地池种植鸢尾＋菖蒲混合植物,同时构建了无植物的对照组湿地。研究表明：（1）在运行初期,沸石和炉渣2种基质对TN、TP的去除率差异为12.5%和12.6%,吸附饱和后,2种基质对TN和TP的去除率差异缩小为3.2%和6.1%,从长期运行来看,炉渣和沸石2种基质在人工湿地中的去除效率差异将减小;（2）茭白单一植物湿地对污染物的去除率与鸢尾＋菖蒲混合植物湿地对污染物的去除率两者之间差异不大;（3）人工湿地种植植物后对TN、TP的去除率比无植物状态时分别高出13.6%和19.5%,植物在人工湿地中对污染物的去除发挥了重要作用;（4）在本试验条件下,茭白吸收所去除的氮数量为湿地氮总去除量的8.95%,茭白吸收去除磷的数量为湿地磷总去除量的20.16%,在人工湿地中,茭白吸收对磷的去除效率比对氮的去除效率高。     

垂直流人工湿地启动期基质酶的时空变化

为了解垂直流人工湿地系统中基质酶在去污效果中的作用及其随基质深度和运行时间的变化规律,设置3个垂直流人工湿地系统:种植皇竹草的A系统,种植象草的B系统,以及不种植物的C系统。分别监测3个系统不同基质深度与不同运行时间条件下脲酶、磷酸酶、过氧化氢酶、转化酶和纤维素酶的变化规律,以及这几种酶与TN、TP、COD、NH+4-N和NO-3-N污染物之间的相关性。实验结果表明,上述5种酶都表现出随着基质深度增加而减少的趋势,且上层0~30cm处的基质酶活性极显著高于中层和底层的酶活性,此外,种植能源植物的A、B系统基质酶活性都高于不种植物C系统,说明湿地中污染物的去除主要集中在上层基质,种植能源植物能够有效促进微生物的活性,增加胞外酶的分泌,提高人工湿地对污染物的去除效果,可为优化人工湿地除污效果以及湿地植物的选择提供理论依据。     

不同基质复合垂直流人工湿地对富营养化景观水的净化效果

研究了两套不同基质复合垂直流人工湿地小试装置在不同季节对富营养化景观水的净化效果,分析了温度变化对污染物去除效果的影响,考察了微生物的硝化强度和反硝化强度以及基质理化性质对植物生长状况的影响,并探讨了氮、磷的去除途径.结果表明:不同基质复合垂直流人工湿地随季节变化对浊度、COD和磷的去除效果差异不明显;温度降低对脱氮效果影响显著,对磷的去除影响不大.沸石-页岩湿地硝化强度和反硝化强度优于砾石湿地.采用沸石作为基质可以提高系统对氮的去除效率,促进湿地植物的生长.对氮、磷去除途径的分析表明:微生物的硝化反硝化作用以及基质对磷的吸附沉淀作用是复合垂直流人工湿地去除氮、磷的主要途径;植物吸收分别占湿地TN、TP去除量的16%和35%左右,也是个重要途径.     

不同基质在人工湿地脱氮中的应用及其研究进展

在比较了不同基质脱氮效率的基础上,认为基质作为人工湿地的重要组成部分,在为植物和微生物提供生长介质的同时,也能通过沉淀、过滤和吸附等作用直接去除污染物质,其中基质的类型、级配等因素会影响基质作用的发挥;不同基质对脱氮性能存在较大差异,沸石和蛭石是目前研究中脱氮效率较高的两种基质。在归纳了脱氮机制和影响因素的基础上,认为不同基质由于脱氮机制不同,脱氮性能和脱氮效率也存在较大差异;人工湿地基质所有理化性状都可能影响到它对污水的脱氮效率。最后,对今后的相关研究方向进行了展望。     

种植不同植物的表面流人工湿地净化效果和微生物群落差异分析

为了解植物种类对表面流人工湿地的净化效果的影响及其与微生物群落的关系,研究了4种植物条件下表面流人工湿地的氮磷平衡以及微生物群落结构。结果表明,各组人工湿地对氨氮(45.53%～80.95%)、总氮(53.67%～80.30%)和总磷(32.97%～55.77%)都有较好的处理效果,种植植物的人工湿地比未种植的人工湿地具有更高的氨氮、总氮和总磷去除效果,其中黄菖蒲组对氮的去除效果最好,美人蕉组对磷的去除效果最好。在表面流人工湿地中,微生物作用(34.84%～45.44%)是人工湿地氮去除的主要途径,基质吸附(20.90%～23.91%)是人工湿地磷去除的主要途径,但是种植植物的人工湿地的氮磷通过微生物去除的量更高。高通量测序分析表明,相较于未种植植物的人工湿地,种植植物的人工湿地显示出更高的微生物丰富度、多样性和更高的脱氮除磷功能微生物的丰度。假单胞菌属、不动杆菌属、芽孢杆菌属和硝化螺菌属是人工湿地中主要的脱氮菌属,也是种植植物的人工湿地高生物脱氮的原因。假单胞菌属和不动杆菌属丰度增加是种植植物的人工湿地高生物除磷的原因。     

人工湿地植物研究进展

人工湿地具有去除污染效果好、运行费用低和易维护等特点,已被广泛用于污水处理中.湿地植物在其中起着重要作用,主要包括直接吸收氮、磷等污染物,通过根系输氧促进根区的氧化还原反应与好氧微生物活动及增强和维持介质的水力传输等.综述了人工湿地植物的去污机理,阐述了湿地植物对生物可降解的有机物、营养性污染物和有毒有害物质净化的研究成果与应用,并展望今后进一步研究的重点.     

无植物潜流人工湿地基质床污染物去除性能研究

采用单一基质页岩和页岩、陶粒组合基质进行无植物潜流人工湿地基质床的水质净化实验,比较不同基质设置对COD、TN、NH+-N、TP、溶解性总磷(TDP)和溶解性正磷酸盐(SRP)去除效果的影响.结果表明,在相同进水水质,水力负荷为480mm/d的运行条件下,以单一页岩为基质的无植物潜流人工湿地基质床的COD、TN、NH4+-N、TP、TDP、SRP去除效果均略优于填充页岩和陶粒组合基质的基质床.总体来看,基质对湿地系统中各污染物去除的贡献均不是非常显著,并且不能保证长期稳定的运行效果.沿程去除结果表明,无植物潜流人工湿地基质床对COD、NH+-N、TP的去除主要发生在进水后沿程的0～90 cm距离内.水力负荷和基质设置均可能影响基质床的污染物去除效果,以基质选择为目的的批量吸附实验结果不能完全反映基质床的全面去污性能.     

水力负荷与有机负荷协同作用对人工湿地微生物群落结构的影响

以单层基质结构(CW1)、3层基质结构(CW3)、6层基质结构(CW6)的水平潜流人工湿地系统为对象,考察水力负荷及有机负荷对不同人工湿地系统去除COD、总悬浮固体(TSS)效果的影响,同时利用高通量测序技术,分析高负荷条件下系统微生物群落结构。结果表明,不同水力负荷运行条件下,随着有机负荷的提高,CW1、CW3、CW6湿地系统对COD、TSS的去除率均表现出先升高后下降的趋势,总体看来,在相同运行条件下CW6湿地系统COD、TSS的去除率最高。群落结构分析表明,不同人工湿地系统微生物结构存在相似性,但湿地床体的基质结构会对微生物群落结构产生一定影响,总的来说分层填充的人工湿地系统微生物群落结构更为稳定,对污染物的去除效果更好。     

Utilising the Synergy between Plants and Rhizosphere Microorganisms to Enhance Breakdown of Organic Pollutants in the Environment (15 pp)

Background Phytoremediation is a promising technology for the cleanup of polluted environments. The technology has so far been used mainly to remove toxic heavy metals from contaminated soil, but there is a growing interest in broadening its applications to remove/degrade organic pollutants in the environment. Both plants and soil microorganisms have certain limitations with respect to their individual abilities to remove/breakdown organic compounds. A synergistic action by both rhizosphere microorganisms that leads to increased availability of hydrophobic compounds, and plants that leads to their removal and/or degradation, may overcome many of the limitations, and thus provide a useful basis for enhancing remediation of contaminated environments.Main Features The review of literature presented in this article provides an insight to the nature of plant-microbial interactions in the rhizosphere, with a focus on those processes that are relevant to the breakdown and/or removal of organic pollutants. Due consideration has been given to identify opportunities for utilising the plant-microbial synergy in the rhizosphere to enhance remediation of contaminated environments.Results and Discussion The literature review has highlighted the existence of a synergistic interaction between plants and microbial communities in the rhizosphere. This interaction benefits both microorganisms through provision of nutrients by root exudates, and plants through enhanced nutrient uptake and reduced toxicity of soil contaminants. The ability of the plant-microbial interaction to tackle some of the most recalcitrant organic chemicals is of particular interest with regard to enhancing and extending the scope of remediation technologies.Conclusions Plant-microbial interactions in the rhizosphere offer very useful means for remediating environments contaminated with recalcitrant organic compounds.Outlook A better knowledge of plant-microbial interactions will provide a basis for improving the efficacy of biological remediations. Further research is, however, needed to investigate different feedback mechanisms that select and regulate microbial activity in the rhizosphere.     

Removal processes for arsenic in constructed wetlands

Arsenic pollution in aquatic environments is a worldwide concern due to its toxicity and chronic effects on human health. This concern has generated increasing interest in the use of different treatment technologies to remove arsenic from contaminated water. Constructed wetlands are a cost-effective natural system successfully used for removing various pollutants, and they have shown capability for removing arsenic. This paper reviews current understanding of the removal processes for arsenic, discusses implications for treatment wetlands, and identifies critical knowledge gaps and areas worthy of future research. The reactivity of arsenic means that different arsenic species may be found in wetlands, influenced by vegetation, supporting medium and microorganisms. Despite the fact that sorption, precipitation and coprecipitation are the principal processes responsible for the removal of arsenic, bacteria can mediate these processes and can play a significant role under favourable environmental conditions. The most important factors affecting the speciation of arsenic are pH, alkalinity, temperature, dissolved oxygen, the presence of other chemical species - iron, sulphur, phosphate -, a source of carbon, and the wetland substrate. Studies of the microbial communities and the speciation of arsenic in the solid phase using advanced techniques could provide further insights on the removal of arsenic. Limited data and understanding of the interaction of the different processes involved in the removal of arsenic explain the rudimentary guidelines available for the design of wetlands systems.     

高盐工业废水人工湿地处理中植物的筛选

通过人工湿地中试实验,考察了芦苇、睡莲、水葱、狭叶香蒲和宽叶香蒲水生植物单元对经生化处理的石油和精细化工工业区的工业废水中盐含量较高、氮磷营养盐含量较低和化学需氧量(COD)含量较高的废水中污染物的去除情况,研究了在植物不同生长阶段系统中COD的去除同盐度之间的关系,探讨了盐度差异对植物生长状况的影响,为确定人工湿地适合的进水盐度,达到有效去除高含盐量工业废水中有机污染物提供依据。结果表明,芦苇、睡莲和狭叶香蒲3种植物单元内高含盐量工业废水中污染物的净化效果较水葱和宽叶香蒲单元的净化效果好:前3种植物单元内COD、生化需氧量(BOD)和总磷(TP)的去除率大约在38%、55%和62%左右,而水葱和宽叶香蒲2种植物单元内COD、BOD和TP的去除率大约在30%、36%和52%左右;系统中各个单元内总氮(TN)去除率都在85%以上。在植物的不同生长阶段,人工湿地系统中氯离子浓度与COD浓度之间的相关性存在差异:植物生长初期,系统中氯离子浓度与系统中COD浓度之间无显著相关性,而在植物生长旺期和末期,两者则成正相关关系。因此,需根据植物的生长阶段调整人工湿地的进水盐度。     

Phytoremediation of polyaromatic hydrocarbons, anilines and phenols

Phytoremediation technologies based on the combined action of plants and the microbial communities that they support within the rhizosphere hold promise in the remediation of land and waterways contaminated with hydrocarbons but they have not yet been adopted in large-scale remediation strategies. In this review plant and microbial degradative capacities, viewed as a continuum, have been dissected in order to identify where bottle-necks and limitations exist. Phenols, anilines and polyaromatic hydrocarbons (PAHs) were selected as the target classes of molecule for consideration, in part because of their common patterns of distribution, but also because of the urgent need to develop techniques to overcome their toxicity to human health. Depending on the chemical and physical properties of the pollutant, the emerging picture suggests that plants will draw pollutants including PAHs into the plant rhizosphere to varying extents via the transpiration stream. Mycorrhizosphere-bacteria and -fungi may play a crucial role in establishing plants in degraded ecosystems. Within the rhizosphere, microbial degradative activities prevail in order to extract energy and carbon skeletons from the pollutants for microbial cell growth. There has been little systematic analysis of the changing dynamics of pollutant degradation within the rhizosphere; however, the importance of plants in supplying oxygen and nutrients to the rhizosphere via fine roots, and of the beneficial effect of microorganisms on plant root growth is stressed. In addition to their role in supporting rhizospheric degradative activities, plants may possess a limited capacity to transport some of the more mobile pollutants into roots and shoots via fine roots. In those situations where uptake does occur (i.e. only limited microbial activity in the rhizosphere) there is good evidence that the pollutant may be metabolised. However, plant uptake is frequently associated with the inhibition of plant growth and an increasing tendency to oxidant stress. Pollutant tolerance seems to correlate with the ability to deposit large quantities of pollutant metabolites in the 'bound' residue fraction of plant cell walls compared to the vacuole. In this regard, particular attention is paid to the activities of peroxidases, laccases, cytochromes P450, glucosyltransferases and ABC transporters. However, despite the seemingly large diversity of these proteins, direct proof of their participation in the metabolism of industrial aromatic pollutants is surprisingly scarce and little is known about their control in the overall metabolic scheme. Little is known about the bioavailability of bound metabolites; however, there may be a need to prevent their movement into wildlife food chains. In this regard, the application to harvested plants of composting techniques based on the degradative capacity of white-rot fungi merits attention.     

Microbial abundance and community in subsurface flow constructed wetland microcosms: role of plant presence

In this research, the role of plants in improving microorganism growth conditions in subsurface flow constructed wetland (CW) microcosms was determined. In particular, microbial abundance and community were investigated during summer and winter in Phragmites australis-planted CW microcosms (PA) and unplanted CW microcosms (control, CT). Results revealed that the removal efficiencies of pollutants and microbial community structure varied in winter with variable microbial abundance. During summer, PA comprised more dominant phyla (e.g., Proteobacteria, Actinobacteria, and Bacteroidetes), whereas CT contained more Cyanobacteria and photosynthetic bacteria. During winter, the abundance of Proteobacteria was >40 % in PA but dramatically decreased in CT. Moreover, Cyanobacteria and photosynthetic bacterial dominance in CT decreased. In both seasons, bacteria were more abundant in root surfaces than in sand. Plant presence positively affected microbial abundance and community. The potential removal ability of CT, in which Cyanobacteria and photosynthetic bacteria were abundant during summer, was more significantly affected by temperature reduction than that of PA with plant presence.     

A review on the application of microbial toxicity tests for deriving sediment quality guidelines

The results of microbial toxicity tests are needed for the risk assessment of polluted sediments. In comparison with animals the anaerobic microorganisms are more tolerant to natural sediment conditions whereas they are more sensitive for a number of specific pollutants. Microbial toxicity tests from a literature search were classified in seven categories. Category A, B and C use polluted sediments and are applied for sediment monitoring. In category D, a pure chemical is added and the organisms and the test conditions were derived from sediment. Therefore this category can be used for setting sediment quality guidelines which protect sediment functions for the toxic effects of chemicals. In category E, organisms from a polluted site are separated from the sediment and are tested with pure chemicals. Organisms from a more polluted site can be more tolerant to a local pollutant. This is called pollution-induced community tolerance and can be used as evidence for the occurrence of toxic effects in a specific sediment. In category F pure chemicals are tested with a pure culture of microorganisms under sediment conditions. The results of category F tests can be combined with single species tests with animals and plants to obtain sediment quality guidelines sufficient for species protection. This can be compared with the sediment quality guidelines which protect sediment functions. When one of these quality guidelines is exceeded for a compound at a specific location a category E test can be used to determine whether the compound shows toxic effects in that sediment.     

进口高效菌用于青藏铁路污水处理应急保障的可行性研究

青藏铁路沿线污水处理安全运营保障体系中,应急状态下需要大量的接种备用活性污泥。在实验室研究基础上,考察了进口高效菌低温低压条件下对污染物的处理能力,最后将其应用到拉萨污水处理厂实际工程。实验室研究及实际对比实验结果表明,高效菌在低温低压下的处理性能和青藏高原实际的活性污泥性能基本相当,如与微生物固定化技术结合使用,可大大增加强化生化处理的效果。进口高效菌具有微生物活性高、培养时间短、保存携带方便,能快速提升生化系统处理能力的优点,可满足青藏线污水处理设施应急状态下处理能力快速提升和安全稳定运行的需要。     

Examination of oxygen release from plants in constructed wetlands in different stages of wetland plant life cycle

The quantification of oxygen release by plants in different stages of wetland plant life cycle was made in this study. Results obtained from 1 year measurement in subsurface wetland microcosms demonstrated that oxygen release from Phragmites australis varied from 108.89 to 404.44 mg O₂/m²/d during the different periods from budding to dormancy. Plant species, substrate types, and culture solutions had a significant effect on the capacity of oxygen release of wetland plants. Oxygen supply by wetland plants was estimated to potentially support a removal of 300.37 mg COD/m²/d or 55.87 mg NH₄-N/m²/d. According to oxygen balance analysis, oxygen release by plants could provide 0.43–1.12 % of biochemical oxygen demand in typical subsurface-flow constructed wetlands (CWs). This demonstrates that oxygen release of plants may be a potential source for pollutants removal especially in low-loaded CWs. The results make it possible to quantify the role of plants in wastewater purification.     

Effects of soil organic matter on the development of the microbial polycyclic aromatic hydrocarbons (PAHs) degradation potentials

The microbial activity in soils was a critical factor governing the degradation of organic micro-pollutants. The present study was conducted to analyze the effects of soil organic matter on the development of degradation potentials for polycyclic aromatic hydrocarbons (PAHs). Most of the degradation kinetics for PAHs by the indigenous microorganisms developed in soils can be fitted with the Logistic growth models. The microbial activities were relatively lower in the soils with the lowest and highest organic matter content, which were likely due to the nutrition limit and PAH sequestration. The microbial activities developed in humic acid (HA) were much higher than those developed in humin, which was demonstrated to be able to sequester organic pollutants stronger. The results suggested that the nutrition support and sequestration were the two major mechanisms, that soil organic matter influenced the development of microbial PAHs degradation potentials.