表流湿地土壤因素对微污染水净化作用

为了研究人工湿地土壤在处理微污染原水的作用,在济南玉清湖水库建立土壤空白床进行实验研究.结果表明,在排除了植物因子的前提下,人工湿地的土壤-微生物系统对微污染原水中COD平均去除率达到46.67%、对TN的平均去除率为34.86%、对NH4 -N的平均去除率分别达到39.83、对TP的平均去除率达到45.12%.系统不同单位区段对微污染原水中的COD、TN、NH4 -N、TP去除率存在差异,在第一个单位区段的处理效率最高,分别为21.5%、18.32%、19.85%和16.64%,远大于第二、三、四区段.另外,土壤吸收附磷的过程中存在着积累现象.而且,系统处理效率受温度影响显著,随着温度的降低,污染物去除率也下降.     

牧草轮作对奶牛场污水氮、磷的净化效果研究

以土壤为基质,选择象草（Pennisetum purpureum）和黑麦草（Lolium perenne）两种牧草作为植被模拟人工湿地净化系统,研究牧草全年轮作在间歇流人工湿地中对奶牛场高质量浓度污水的适应性及对污水氮、磷的净化效果。结果表明：象草、黑麦草在间歇性高质量浓度污水中生长良好,可作为畜牧场高质量浓度污水修复植物进行全年轮作,并适时的收割,去除污水中的氮、磷。在不同污水质量浓度处理的牧草净化系统中,水力停留时间为8 d的条件下,铵氮的去除率为75.9%~94.9%;硝态氮的去除率为65.4%~90.9%;总氮的去除率64.2%~90.1%;总磷的去除率在90%以上;象草和黑麦草对污水中氮、磷的吸收转化在系统对氮磷净化中的贡献率平均分别为氮25.12%和20.03%、磷31.20%和20.42%;各处理氮、磷的去除效果与污水的质量浓度呈负相关。     

表面流人工湿地中氮磷的去除机理

人工湿地作为一种高效、低耗的污水处理新工艺已被广泛接受，特别是其在脱氮、除磷方面的应用逐步为人们所重视。本文深入地讨论了表面流人工湿地中各种生物、物理、化学过程对污水中各种形态含氮、含磷化合物的去除机理，及其具体途径、相关反应和反应类型，总结了国内外对各个过程影响因素、控制条件、反应速度、去除能力及相互之间协调拮抗作用的研究结果。虽然硝化／反硝化作用和土壤吸附沉淀作用已被公认为是表面流人工湿地脱氮、除磷的主要途径，但不同研究结果之间仍存在着明显差异，鲜有多介质环境条件下各种脱氮、除磷过程中多种氮、磷形态的质量平衡研究，而以此为基础的人工湿地生态动力学模型的研究则是深入了解人工湿地运行机理、设计和预测其处理效率，以及推动人工湿地污水处理工艺广泛应用的关键。     

芦苇人工湿地对农村生活污水磷素的去除及途径

构建了芦苇(Phragmites australis)水平潜流人工湿地处理农村生活污水中的磷素,考察了湿地除磷效果以及地上植物吸磷量。结果表明,人工湿地对磷素的去除随水力停留时间的延长而增加,停留时间大于5.3 d时,芦苇湿地除磷效率可以高于88%。湿地进水TP负荷与磷去除速率之间有较好的线性关系(R2>0.91)。湿地植物在11月份收割时,地上生物量为1.65 kg.m-2,芦苇地上部分吸收磷量为3.68 g.m-2.a-1。分析了湿地除磷途径,在试验条件下,湿地填料的吸附和沉淀等作用是水平潜流人工湿地除磷的主要途径,植物吸收仅占湿地总磷去除量的9.1%,但是湿地水生植物是人工湿地重要组成部分,可以通过影响湿地的其他条件间接影响湿地除磷效果。试验证明,人工湿地是适用于农村地区的优良的污水处理技术。     

模拟试验初探秋茄湿地系统中锌的分配与土壤容量

对温室中建立的含底泥、潮汐海水和１ａ生秋茄苗的模拟湿地系统,分别用人工海水（ＣＫ）和不同Ｚｎ浓度的人工污水定时、定量进行持续１ａ的污灌,以研究Ｚｎ在模拟系统中各部分的分配和系统对Ｚｎ的承受能力．结果表明：加入系统的３种ρ（Ｚｎ）处理污水中的Ｚｎ主要存留在土壤中（４５．８０％～８９．４５％）,植物和凋落物中的Ｚｎ共占加入量０．２２％～１．４８％．根据物质平衡模型计算得的系统使用寿命ｔ至少为２４ａ．     

地沟式污水土地处理+人工湿地中植物对磷的去除效果

采用盆栽实验和中试实验系统，研究了地沟式土地处理系统和人工湿地中不同植物对磷的去除效率。选取贵州省典型的7种植物——美人蕉、芋头、八仙花、小玉竹、杜鹃、菖蒲、岩豆藤作为供试物。结果表明，7种试验植物对生活污水中的磷均有很高的净化率，其中以芋头、菖蒲和岩豆藤等3种植物对磷的净化效率最高。文章同时还对中试各处理槽的不同位置和深度的土壤中的微生物种类和数量进行了分析，进一步阐述了地沟式土地处理系统和人工湿地中植物的除磷机理。     

潮汐流人工湿地处理含双酚A污水

本研究利用潮汐流人工湿地处理技术处理含双酚A污水.研究结果表明,潮汐流人工湿地的最佳淹没反应时间和空床闲置时间均为24 h;在最佳运行条件下,芦苇床湿地对污水中COD_(Cr)、NH_3-N、NO_2-N、NO_3-N、TP、SS各污染物指标的去除效果比香蒲床湿地略高,而对双酚A的去除效果要略低于香蒲床湿地,其中芦苇床湿地对双酚A的去除率在74%—96%之间,香蒲床湿地对双酚A的去除率在70%—83%之间.芦苇和香蒲根际土壤多酚氧化酶活性在1.47—3.19 mg·g~(-1)之间,其中香蒲根际土壤多酚氧化酶活性高于芦苇,芦苇床和香蒲床潮汐流人工湿地系统都适合含双酚A城镇污水的处理.     

人工湿地的磷去除机理

人类生产和生活所产生的磷负荷导致了全中国范围湖泊的富营养化,控制此磷负荷的廉价而有效的具有非常广阔的应用前景技术是人工湿地技术。人工湿地中的磷的存在形态主要有有机磷(生物态和非生物态的)、磷酸、可溶性磷酸盐和不溶性磷酸盐。文章总结了人工湿地中的磷去除机理,在防渗人工湿地系统中,主要的磷去除机理包括化学作用(如沉淀作用和吸附作用);生物作用(如植物吸收作用和微生物吸收与积累作用)和物理作用(如沉积作用)。在未防渗的人工湿地系统中,湿地系统和周围水体(如地下水)的交换量对湿地的磷去除有重要的影响。通常情况下,物理作用和化学作用是人工湿地中最主要的磷去除途径。人工湿地中微生物对磷的去除作用的大小和其所处环境中的氧状态密切相关,植物吸收对磷的去除作用的大小和收割频率与时期、进水负荷、植物物种和气候条件等有关。     

几种植物在生长过程中对人工湿地污水处理效果的影响

不同的植物及植物的不同生长阶段对人工湿地系统污水处理效果都有影响。对几种华南地区常见的湿地植物在其不同生长阶段处理污水的效果进行了研究,采用了不种植物的沙滤系统作对照。结果表明:(1)植物生长过程中,植物高度能反映污水处理效果总体上的变化;(2)在植物的生长过程中,各人工湿地系统污水处理能力总体上持续增强,各水质指标pH、DO、TN、NH3-N、NO3-N、TP和CODCr等均呈下降趋势,其中TP和CODCr呈逐步下降,pH、DO、TN、NH3-N、NO3-N则呈现锯齿形波动,但总体上仍是下降过程;(3)植物系统氮处理能力好于无植物沙滤系统,而对磷TP和CODCr的去除则恰好相反;(4)不同植物对人工湿地污水的处理效果影响不明显。研究结果对探讨人工湿地污水处理规律和植物在人工湿地中的作用提供了新的科学依据,并为指导人工湿地工程的运行提供了参考。     

人工湿地土壤微生物生物量碳与污水净化效果的关系

微生物在人工湿地污水净化过程中发挥着重要作用,微生物生物量碳是微生物的重要表征之一.为探讨人工湿地土壤微生物量碳与污水净化效果的关系,以表面流人工湿地为研究对象,分别研究了不同植物人工湿地土壤微生物生物量碳和净化效果的时空变化及其相关性.结果显示,4种植物湿地表层(0-5 cm)微生物生物量碳极显著高于深层(15-20 cm)的测量值(P<0.01).人工湿地污染物去除效果与微生物生物量碳具有相同的季节变化规律,都呈单峰型的季节格局,夏秋季较高,冬春季较低.微生物生物量碳与人工湿地COD、BOD5和TN的去除呈显著正相关(P<0.05).水鬼蕉湿地具有较高的微生物生物量碳,而污染物去除率一般较低,这表明不同湿地微生物生物量碳与污染物去除率的相关性呈现不确定性.     

湖滨带复合型人工湿地氮磷的去除效果

湖滨带是连接湖泊水域生态系统与陆地生态系统的一个功能过渡区,是湖泊的最后一道保护屏障。在河流的入湖口建造湖滨湿地,可有效净化入湖径流中携带的部分有机污染物、营养盐等。以云南抚仙湖北岸的湖滨湿地—马料河复合人工湿地为研究对象,探讨了湿地不同功能区去除氮磷的效果。研究表明,沉淀池除氮效果最不明显,在该区内有机氮可能发生矿化作用而转变为氨氮。有植物系统的潜流和表流区除氮效果较为明显,潜流区对氨氮、硝氮和总氮的平均去除率分别达18.0%、19.7%和22.6%;表流区对三者的平均去除率分别达50.4%、35.9%和43.5%。沉淀池对磷有一定的截留作用,且在进水污染物质量浓度较高时表现明显,平均截留率为14.9%。潜流和表流区除磷效果不明显,可能是因为湿地运行了两年多,土壤吸附交换达到平衡,影响了表流区的除磷效果。潜流区除磷效果受降雨影响较大,雨季时,总磷的平均截留率为12.1%,主要是不溶性磷的吸附和沉积;雨季末期,湿地流量较小,水体流动性差,系统内处于厌氧状态,出现磷释放现象。     

Control division of agricultural non-point source pollution at medium-sized watershed scale in Southeast China

This paper presents the study carried out for controlling agricultural non-point source pollution (NSP) in a medium-sized watershed covering 1.47 × 10⁴ km² in Southeast China using quantitative analysis coupled with geographic information system (GIS), universal soil loss equation (USLE), soil conservation service-curve number (SCS-CN), nutrient loss equations, and annualized agricultural nonpoint source model (AnnAGNPS). Based on the quantitative results derived from GIS and environmental models, five control division units were generated for NSP control in Jiulong River watershed, namely, controlling unit for soil losses, controlling unit for livestock breeding and soil losses, controlling unit for excessive fertilizer use and livestock breeding, controlling unit for soil losses and fertilizer use, and controlling unit for excessive fertilizer use and soil losses. This study proved that integrating GIS with environmental models can be adopted to efficiently evaluate major sources and contributors of NSP, and identify the critical source areas of NSP, which enables adjusting measures to local conditions by further control division units developed through such study for control and management of water quality degradation induced by NSP in the Jiulong River watershed.     

Relationships between loading rates and nitrogen removal effectiveness in subsurface flow constructed wetlands

Nitrogen removal of wetlands under 40 different inflow loadings were studied in the field during 15 months. The removal efficiency of four different sets of beds, namely the reed bed, the Zizania caduciflor bed, the mixing planting bed, and the control bed were studied. The outflow loading and total nitrogen (TN) removal rate of these beds under different inflow loadings and pollution loadings were investigated. The inflow loadings of 4 subsurface flow systems (SFS) ranged from 400 to 8000 mg·(m²·d)^?1, while outflow loadings were less than 7000 mg·(m²·d)^?1. The results showed that the inflow and outflow loading of TN removal rate in SFS presented an obvious linear relationship. The optical inflow loading to run the system was between 2000 to 4000 mg·(m²·d)^?1. Average removal rate was between 1062 and 2007 mg·(m²·d)^?1. SFS with plant had a better removal rate than the control. TN removal rates of the reed and Zizania caduciflora bed were 63% and 27% higher than the control bed, respectively. The results regarding the TN absorption of plants indicated that the absorption amount was very limited, less than 5% of the total removal. It proved that plants clearly increase TN removal rates by improving the water flow, and increasing the biomass, as well as activities of microorganisms around the roots. The research provided a perspective for understanding the TN removal mechanism and design for SFS.     

A Biosurfactant-Enhanced Soil Flushing for the Removal of Phenanthrene and Diesel in Sand

In order to examine the potential of biosurfactants in soil remediation, and to investigate the effects of several operating conditions, such as flow rate, biosurfactant concentration and surfactant type, biosurfactant-enhanced soil flushing was conducted. In the biosurfactant-enhanced soil flushing process, the removal efficiency increased as the flow rate decreased. Rhamnolipid showed no effect on the removal efficiency of phenanthrene and diesel from sand in the concentration range 0.3-0.5%. However, rhamnolipid showed higher efficiencies for the removal of phenanthrene and diesel from sand than Tween 80. Based on total recovery, following an equivalent pore volume flush, it was more difficult to remove diesel than phenanthrene. In order to obtain the specific removal efficiency, more pore volumes of surfactant solution may be required in field applications. Under optimum conditions, the biosurfactant removed as much as 70% of the phenanthrene and 60% of the diesel in the sand. These results indicate that the use of biosurfactants in the flushing process is favorable, not only with respect to the environment, but also on removal efficiencies.     

水作和旱作对叶菜吸收镉的影响差异研究

采用盆栽试验,以适宜水旱2种模式栽培的空心菜（Ipomoea aquatica）为对象,研究了水作和旱作两种栽培模式对Cd污染土壤上空心菜吸收积累Cd的差异及其影响因素。结果表明,水作和旱作对空心菜生物量和Cd质量分数影响显著。水作条件下,空心菜地上部和根系生物量分别比旱作处理增加了16.3%和190.6%,而地上部和根系Cd质量分数则较旱作处理降低了52.2%和49.3%。水作和旱作对土壤pH和DTPA-Cd质量分数也有不同影响,其中种植空心菜的处理土壤pH较旱作处理增加了0.99个单位,土壤DTPA-Cd质量分数降低了40.0%,不种空心菜的处理土壤pH较旱作处理增加了1.48个单位,土壤DTPA-Cd质量分数降低了30.4%。逐步回归分析发现,空心菜地上部Cd质量分数受土壤DTPA-Cd质量分数和土壤pH影响最大。因此,在Cd污染土壤上,通过旱作改水作可降低空心菜可食部分Cd质量分数,是一种环境友好、价格低廉的土壤重金属污染的调控措施。     

土壤渗滤系统中污染物去除效果分析

在土壤渗滤系统中,水力负荷、有机负荷和碳氮比等因素均对营养盐的处理效率具有显著影响.在实验室控温条件下,分析了不同水力负荷、有机负荷和环境条件对土壤渗滤系统污染物去除效果的影响.结果表明,在水力负荷小于0.15 m3·m^-2·d^-1的条件下,模拟生活污水中CODCr、总氮和总磷去除率分别达到84％、37％和93％以上,土壤（以干土计）亚硝酸盐细菌数量为4.50× 106 g^-1.装置上层产生的滞水对CODCr和磷酸盐的去除影响不大,但是由于处理系统内溶解氧浓度降低,使得氨氮硝化过程受到抑制,氨氮和总氮的处理效果均变差;在通气良好条件下,较高的碳氮比[m（碳）：m（氮）=5：1]对系统中总氮的去除更为有利.     

Methanation and chemolitrophic nitrogen removal by an anaerobic membrane bioreactor coupled partial nitrification and Anammox

● Efficient carbon methanation and nitrogen removal was achieved in AnMBR-PN/A system. ● AOB outcompeted NOB in PN section by limiting aeration and shortening SRT. ● The moderate residual organic matter of PN section triggered PD in anammox unit. ● AnAOB located at the bottom of UASB played an important role in nitrogen removal. An AnMBR-PN/A system was developed for mainstream sewage treatment. To verify the efficient methanation and subsequent chemolitrophic nitrogen removal, a long-term experiment and analysis of microbial activity were carried out. AnMBR performance was less affected by the change of hydraulic retention time (HRT), which could provide a stable influent for subsequent PN/A units. The COD removal efficiency of AnMBR was > 93% during the experiment, 85.5% of COD could be recovered in form of CH₄. With the HRT of PN/A being shortened from 10 to 6 h, nitrogen removal efficiency (NRE) of PN/A increased from 60.5% to 80.4%, but decreased to 68.8% when the HRT_PN/A further decreased to 4 h. Microbial analysis revealed that the highest specific ammonia oxidation activity (SAOA) and the ratio of SAOA to specific nitrate oxidation activity (SNOA) provide stable NO₂⁻-N/NH₄⁺-N for anammox, and anammox bacteria (mainly identified as Candidatus Brocadia) enriched at the bottom of Anammox-UASB might play an important role in nitrogen removal. In addition, the decrease of COD in Anammox-UASB indicated partial denitrification occurred, which jointly promoted nitrogen removal with anammox.     

Characteristics and removal mechanism of the precursors of N-chloro-2,2-dichloroacetamide in a drinking water treatment process at Taihu Lake

• N-Cl-DCAM, an emerging N-DBP in drinking water was investigated. • A new BAC has a better removal efficiency for N-Cl-DCAM precursors than an old BAC. • N-Cl-DCAM precursors are more of low molecular weight and non-polar. • Adsorption of GAC plays a major role in removal of N-Cl-DCAM precursors by an O₃-BAC. N-chloro-2,2-dichloroacetamide (N-Cl-DCAM) is an emerging nitrogenous disinfection by-product (N-DBP) which can occur in drinking water. In this study, an analytical method based on liquid chromatography with tandem mass spectrometry (LC-MS/MS) was developed to validate the concentration of N-Cl-DCAM, which was found to be 1.5 mg/L in the effluent of a waterworks receiving raw water from Taihu Lake, China. The changes of N-Cl-DCAM formation potential (N-Cl-DCAMFP) in the drinking water treatment process and the removal efficiency of its precursors in each unit were evaluated. Non-polar organics accounted for the majority of N-Cl-DCAM precursors, accounting for 70% of the N-Cl-DCAM FP. The effect of conventional water treatment processes on the removal of N-Cl-DCAM precursors was found to be unsatisfactory due to their poor performance in the removal of low molecular weight (MW) or non-polar organics. In the ozonation integrated with biological activated carbon (O₃-BAC) process, the ozonation had little influence on the decrease of N-Cl-DCAM FP. The removal efficiency of precursors by a new BAC filter, in which the granular activated carbon (GAC) had only been used for four months was higher than that achieved by an old BAC filter in which the GAC had been used for two years. The different removal efficiencies of precursors were mainly due to the different adsorption capacities of GAC for individual precursors. Low MW or non-polar organics were predominantly removed by GAC, rather than biodegradation by microorganisms attached to GAC particles.     

Removal of tetrachlorobisphenol A and the effects on bacterial communities in a hybrid sequencing biofilm batch reactor-constructed wetland system

SBBR-CW system was proposed to effectively treat wastewater containing TCBPA. CW unit contributed more than SBBR to the removal of TCBPA. TCBPA changed the composition and structure of bacterial community in the system. GAOs massively grew in SBBR, but did not deteriorate TP removal efficiency. Tetrachlorobisphenol A (TCBPA) released into the sewage may cause environmental pollution and health risk to human beings. The objective of this study was to investigate the removal of TCBPA and bacterial community structures in a laboratory-scale hybrid sequencing biofilm batch reactor (SBBR)-constructed wetland (CW) system. The results showed that the removal efficiency of chemical oxidation demand (COD), ammonia, total nitrogen and total phosphorus in the SBBR-CW system was 96.7%, 97.3%, 94.4%, and 88.6%, respectively. At the stable operation stage, the system obtained a 71.7%±1.8% of TCBPA removal efficiency with the influent concentration at 200 mg/L. Illumina MiSeq sequencing of 16S rRNA gene revealed that the presence of TCBPA not only reduced the bacterial diversity in the SBBR-CW system, but also altered the composition and structure of bacterial community. After the addition of TCBPA, Proteobacteria increased from 31.3% to 38.7%, while Acidobacteria and Parcubacteria decreased greatly in the SBBR. In contrast, Acidobacteria replaced Proteobacteria as the dominant phylum in the upper soils of CW. The results indicated that TCBPA stimulated the growth of GAOs in the SBBR without deteriorating the phosphorus removal due to the presence of sufficient carbon sources. The ammonia oxidizing bacteria, Nitrosomonas, and denitrification bacteria, Hyphomicrobium and Pseudomonas, were inhibited by TCBPA, resulting in a decreasing the removal efficiency of TN and ammonia.     

Removal of pentachlorophenol from contaminated soil by catalytic oxidation with iron(III)-porphyrin complexes and potassium monopersulfate

Pentachlorophenol (PCP) in contaminated soil was removed by treatment with aqueous solutions of iron(III)-porphyrin complexes as catalysts and potassium monopersulfate (KHSO₅) as the oxygen donor. The contaminated soils were artificially prepared by spiking PCP to the kaolin and ando soils. Three types of iron(III)-porphyrin complexes, tetra(?p-sulfophenyl) porphineiron(III) (Fe(III)-TPPS), tetra(N-methyl-4-pyridil)porphineiron(III) (Fe(III)-TMPyP) and heme, were examined, and Fe(III)-TPPS was found to be the most effective for removing PCP. Although the sequential addition of KHSO₅ was examined, in an attempt to improve the efficiency of PCP removal, it was not effective. In a preliminary test of various aqueous solutions, the addition of humic acid (HA), with a lower degree of humification, led to a significant enhancement in PCP removal. When HA was added to the soil system, the percentages of PCP removal were increased by up to 10% compared to the absence of HA. Therefore, the addition of HA to the catalytic system was useful in enhancing PCP removal from contaminated soil.