Microbial oxidation of 1,2-dichloroethane under anoxic conditions with nitrate as electron acceptor in mixed and pure cultures

Many organisms have been found to readily oxidize the prevalent contaminant 1,2-dichloroethane (1,2-DCA) to CO2 under aerobic conditions. Some organisms have also been isolated that can reduce 1,2-DCA to ethene via dihaloelimination under anaerobic, fermentative conditions. However, none have been described that can metabolize 1,2-DCA under anoxic, nitrate-reducing conditions. In microcosms prepared from aquifer material and groundwater samples from a contaminated site in eastern Louisiana, USA, 1,2-DCA was observed to degrade with nitrate as the terminal electron acceptor. Nitrate-dependent enrichment cultures were developed from these microcosms that sustained rapid 1,2-DCA degradation rates of up to 500 microM day(-1). This degradation was tightly coupled to complete reduction of nitrate via nitrite to nitrogen gas. A novel 1,2-DCA-degrading organism belonging to the Betaproteobacteria (affiliated with the genus Thauera) was isolated from this enrichment culture. However, degradation rates were much slower in cultures of the isolate than observed in the parent mixed culture. Complete mineralization of 1,2-DCA to CO2 was linked to cell growth and to nitrate reduction in both enrichment and isolated cultures. Monochloroacetate, a putative metabolite of 1,2-DCA degradation, could also be mineralized by these cultures.     

Redox processes of sulfur and manganese in a constructed wetland

Constructed wetlands are very popular in terms of wastewater treatment today. Formation of redox potential gradients inside such a system strongly influences the wastewater-treatment efficiency. Individual oxidation forms of sulfur, and dissolved and precipitated manganese forms were determined in the vegetation bed of the constructed wetland. The aim of the speciation analysis was to contribute to the characterization of its redox properties. Sulfur was mostly oxidized at the inflow. The concentration of sulfates at the inflow varied from 25 to 55 mg/l, while concentration of sulfides was always lower than 6.0 mg/l and mostly even lower than 1.0 mg/l. However, sulfates were reduced during the pretreatment and the wastewater flow through the vegetation bed. The concentration of total manganese varied from 0.2 to 0.8 mg/l. Approximately 60% of Mn was precipitated at the inflow. The content of precipitated Mn forms declined to ca. 40-50% at the inflow zone, this content was almost constant across the vegetation bed to the outflow when water was sampled from 60-cm depth. However, the content of precipitated Mn forms increased to ca. 74% for samples from 20-cm depth. With respect to the aeration of the system, manganese can be precipitated as MnO2 in these samples.     

Anaerobic dechlorination of trichloroethene,tetrachloroethene and 1,2-dichloroethane by an acetogenic mixed culture in a fixed-bed reactor

An anaerobic enrichment culture with glucose as the sole source of carbon and energy plus trichloroethene (TCE) as a potential electron acceptor was inoculated with material from a full size anaerobic charcoal reactor that biologically eliminated dichloromethane from contaminated groundwater (Stromeyer et al. 1991). In subcultures of this enrichment complete sequential transformation of 10 µM TCE viacis-dichloroethene and chloroethene to ethene was reproducibly observed. Maintenance of this activity on subcultivation required the presence of TCE in the medium. The enrichment culture was used to inoculate an anaerobic fixed-bed reactor containing sintered glass Raschig elements as support material. The reactor had a total volume of 1780 ml and was operated at 20 °C in an up-flow mode with a flow rate of 50 ml/h. It was fed continuously with 2 mM glucose and 55 µM TCE. Glucose was converted to acetate as the major product and to a minor amount of methane; TCE was quantitatively dehalogenated to ethene. When, in addition to TCE, tetrachloroethene or 1,2-dichloroethane were added to the system, these compounds were also dehalogenated to ethene. In contrast, 1,1,1-trichloroethane was not dehalogenated, but at 40 µM severely inhibited acetogenesis and methanogenesis. When the concentration of TCE in the feed was raised to 220 µM, chloroethene transiently accumulated, but after an adaptation period ethene was again the only volatile product detected in the effluent. The volumetric degradation rate at this stage amounted to 6.2 µmol/l/h. Since complete transformation of TCE occurred in the first sixth of the reactor volume, the degradation capacity of the system is estimated to exceed this value by factor of about ten.Abbreviations CA chloroethane - 1,1-DCA 1,1-dichloroethane - 1,2-DCA 1,2-dichloroethane - 1,1-DCE 1,1-dichloroethene - c-DCE cis-1,2-dichloroethene - t-DCE trans-1,2-dichloroethene - PCE tetrachloroethene, perchloroethene - 1,1,1-TCA 1,1,1-trichloroethane - TCE trichloroethene - VC chloroethene, vinyl chloride     

Decolorization and mineralization of Amaranth dye using multiple zoned aerobic and anaerobic baffled constructed wetland

The objective of this study is to determine the reduction efficiency of Chemical Oxygen Demand (COD) as well as the removal of color and Amaranth dye metabolites by the Aerobic–anaerobic Baffled Constructed Wetland Reactor (ABCW). The ABCW reactor was planted with common reed (Phragmite australis) where the hydraulic retention time (HRT) was set to 1 day and was fed with synthetic wastewater with the addition of Amaranth dye. Supplementary aeration was supplied in designated compartments of the ABCW reactor to control the aerobic and anaerobic zones. After Amaranth dye addition the COD reduction efficiency dropped from 98 to 91% while the color removal efficiency was 100%. Degradation of azo bond in Amaranth dye is shown by the UV–Vis spectrum analysis which demonstrates partial degradation of Amaranth dye metabolites. The performance of the baffled unit is due to the longer pathway as there is the up-flow and down-flow condition sequentially, thus allowing more contact of the wastewater with the rhizomes and micro-aerobic zones.     

不同基质和不同植物对人工湿地净化效率的影响

实验通过建立不同模式的小型湿地系统研究了不同基质和不同的植物组合对人工湿地净化效率和效率稳定性的影响.结果表明,种植植物的湿地系统比没有植物的湿地系统净化效率高,沙土混合基质比卵石基质净化效率高;旱伞草和美人蕉组合以及旱伞草、美人蕉和芦苇3种植物的组合湿地系统比单一旱伞草湿地系统的净化效率更高;小粒径基质和混合种植湿地系统能够保持较稳定的净化效率.     

氮沉降对黄河三角洲芦苇湿地土壤呼吸的影响

2012年6月至2012年10月, 对黄河三角洲芦苇(Phragmites australis)湿地进行了模拟氮沉降试验, 氮沉降水平分别为对照(CK, 0 kg N·hm^-2·a^-1)、低氮(LN, 50 kg N·hm^-2·a^-1)和高氮(HN, 100 kg N·hm^-2·a^-1)。利用LI-8100土壤碳通量测量系统测定土壤呼吸速率。结果表明, 氮沉降促进了芦苇湿地土壤呼吸作用, LN和HN处理使芦苇生长季(6-10月)平均土壤呼吸速率比CK分别提高19%和58%。积水改变了芦苇湿地土壤呼吸日动态。地面无积水时, 各处理土壤呼吸日动态均呈单峰型曲线; 地面有积水时, 土壤呼吸日动态峰值推后或无单峰型波动规律。积水影响土壤呼吸作用对温度的响应。地面无积水时, 各处理土壤呼吸速率均与气温呈极显著的正指数相关关系, 气温分别解释了CK、LN和HN处理下土壤呼吸季节变化的69.9%、64.5%和59.9%; 地面有积水时, 各处理土壤呼吸与气温相关性不显著。CK、LN和HN处理下土壤呼吸温度敏感性系数Q₁₀值分别为1.68、1.75和1.68, 表明LN处理增强了土壤呼吸温度敏感性, HN处理对其影响不显著。     

人工湿地植物对观赏水中氮磷去除的贡献

研究了处理观赏用轻度富营养化水的人工湿地中植物的生长特性和氮磷去除作用。研究发现 ,所选用的 2 1种植物中 ,有17种植物在人工湿地中生长良好 ,稳定生长 10 5 d以后 ,其平均总生物量在 15 5～ 1317g/ m2之间 ,除了鸭跖草的地上地下生物量比 (A/ U)为 2 0 .5外 ,其余都在 1.18～ 4 .2 9之间。植株地上部 N和 P的浓度分别在 10 .99～ 34.74 mg/ g和 0 .5 9～ 3.81mg/ g之间 ;地下部 N和 P浓度分别在 6 .2 0～ 2 9.5 0 mg/ g及 0 .72～ 3.83mg/ g之间。大部分植物地上部 N和 P的浓度大于地下部 (p<0 .0 5 )。植物的 N、P积累量分别在 2 .10～ 2 4 .4 8g/ m2 和 0 .2 3～ 1.95 g/ m2 之间。在处理轻度富营养化水的人工湿地中 ,植物吸收对氮磷的去除起着主要作用——贡献率分别为 4 6 .8%和 5 1.0 %。植物的氮磷积累量与浓度及生物量之间均存在显著相关 ,所以可以直接以生物量为指标选择人工湿地植物。同时考虑净化和景观效果 ,可为处理城镇轻度富营养化水的人工湿地的植物选择提供参考     

Nitrous oxide emissions from surface flow and subsurface flow constructed wetland microcosms: Effect of feeding strategies

The effects of continuous and intermittent feeding strategies on nitrogen removal and N₂O emission from surface flow and subsurface flow constructed wetlands were evaluated in this study. Microcosm wetlands planted with Phragmites australis were constructed and operated with different feeding strategies for the 4-month experiment. Results showed the intermittent feeding strategy could enhance the removal of ammonium effectively in the subsurface flow constructed wetlands, although it had no significant effect for the surface flow wetlands. And the intermittent feeding mode could promote the emission of N₂O. The amount of N₂O-N emission from the subsurface flow constructed wetlands with intermittent feeding mode was about 5 times higher than that with continuous feeding strategy and the emission rate ranged from 0.09 ± 0.03 to 7.33 ± 1.49 mg/m²/h. Compared with the surface flow constructed wetlands, the N₂O emission in the subsurface flow constructed wetlands was affected significantly by the intermittent feeding mode.     

人工湿地除磷研究进展

从人工湿地除磷机理着手,综述了国内外有关湿地基质、湿地植物及微生物强化除磷的研究机理以及进展。深入研究多种基质组合对磷素的吸附与解析机理,可以从理论上推进诸多高效除磷基质的实际应用进程;植物间接净化作用及其与湿地水力停留时间的关系,是影响湿地植物选种和种植的重要依据;植物根际微环境以及植物与微生物的耦合作用可能是人工湿地除磷的主要途径之一;强调湿地的污水净化功能而忽视其生态服务功能,是湿地运行中普遍存在的认识错误。最后指出：湿地运行应采取高水力负荷、低污染负荷的方式,强调强化一级处理的重要性。     

Influence of Agapanthus africanus on nitrification in a vertical subsurface flow constructed wetland

The aim of this study is to evaluate the influence of Agapanthus africanus (A. africanus) on nitrification in a vertical subsurface flow constructed wetlands (VSSFs) system. Two lab-scale VSSFs were operated: a) one was planted with A. africanus (vertical flow planted, VFP), and b) the other was unplanted (vertical flow control, VFC). The operation strategy was divided into three phases and consisted of increasing the ammoniacal nitrogen loading rate (ALR) (Phase I: 1.4; Phase II: 2.4; Phase III: 4.4 g NH₄⁺-N·m^?2·d^?1). Nitrification was evaluated in the system at two different depths in the VSSFs (30.5 cm and 60.3 cm, from the top of the system).

The removal efficiencies of COD, BOD₅, TP, and PO₄^?3-P were above 40% in the VFP and VFC during all operation. The mean removal efficiencies of NH₄⁺-N were above 70%. Nitrification was the principal NH₄⁺-N removal mechanism in both systems and transformed more than 50% of the NH₄⁺-N to NO₃^?-N. In terms of the effect of A. africanus on NH₄⁺-N removal during the three operational phases, nonsignificant differences between the two VSSFs were noted (p > 0.05). Thus, A. africanus did not influence nitrification. Finally, the analysis at different depths showed that nitrification occurred in the upper 30.5 cm.     

高风险四环素抗性基因在人工湿地中分布和去除的季节变化

畜禽养殖废水是抗生素抗性基因(ARGs)的重要贮存库,环境风险不容忽视。本研究考察了夏、冬两季养猪废水中高环境风险四环素抗性基因(TRGs)在水平潜流人工湿地中的分布和去除情况,通过外源添加四环素(TC)和铜离子(Cu²⁺)探究了养猪废水中抗生素与重金属单一和复合污染对湿地出水中TRGs丰度的影响。结果表明: 养猪废水中3种高环境风险TRGs(tetM、tetO、tetW)均有检出,人工湿地可有效消减废水中的TRGs,夏、冬两季时出水中TRGs的绝对丰度较进水分别降低1.1～2.4和1.7～2.9个数量级。TRGs在湿地土壤中的丰度呈现出水端低于进水端、植物非根际低于根际、冬季低于夏季的特征。与对照相比,养猪废水中TC、Cu²⁺单一和复合污染在夏、冬两季均会导致湿地出水中TRGs相对丰度的增加。人工湿地作为一种生态处理工艺可用于控制畜禽养殖废水中的ARGs向环境中扩散。     

植物吸收在人工湿地去除氮、磷中的贡献

探讨了植物在人工湿地系统处理污水中的作用,并分析了影响植物生长的主要环境因素,结合实例分析了湿地植物吸收氮磷在不同生长期的变化和其在去除氮磷营养物中的贡献,认为通过秋冬季的植物收割去除的氮磷量比较低,植物可以作为冬季保温材料而不收割,提出通过组合技术来改善破人工湿地氮磷去除能力的思路.     

黄河口不同恢复阶段湿地土壤N2O产生过程对氮输入的响应

以黄河口生态恢复前后未恢复区(R₀)、2007年恢复区(R₂₀₀₇)和2002年恢复区(R₂₀₀₂)的芦苇湿地为研究对象,研究了不同形态氮输入对湿地土壤N₂O产生过程的影响与贡献.结果表明: 硝态氮(NO₃^--N)输入对恢复区湿地土壤N₂O总产生量的影响远远大于铵态氮(NH₄⁺-N),但两者均抑制了R₀土壤的N₂O总产生量.尽管NO₃^--N输入对R₂₀₀₂表层土壤N₂O总产生量的影响明显大于R₂₀₀₇,但二者的N₂O产生量均随氮输入量的增加而增加.恢复区湿地土壤的反硝化作用和硝化细菌反硝化作用受NO₃^--N输入的影响明显,而R₀土壤产生N₂O的生物过程受其影响并不显著.尽管NH₄⁺-N输入对湿地土壤N₂O的总产生量影响不大,但其输入整体促进了R₀ 土壤的硝化细菌反硝化作用、R₂₀₀₇土壤的硝化作用和R₂₀₀₂土壤的非生物作用.比较而言,NO₃^--N输入对R₀、R₂₀₀₇和R₂₀₀₂湿地土壤N₂O产生的非生物作用主要表现为抑制,NH₄⁺-N输入则整体提高了R₀和R₂₀₀₂湿地土壤非生物作用的N₂O产生量,这与不同形态氮输入对土壤pH的调节作用密切相关.研究发现,NO₃^--N输入大大增加了湿地土壤的N₂O总产生量,改变了原有湿地土壤生物作用和非生物作用的贡献模式,故生态恢复工程导致的营养盐输入(NO₃^--N)应受到特别关注.     

人工湿地对抗生素复合污染的净化效果及微生物群落响应

为研究人工湿地对氟喹诺酮类(FQs)、磺胺类(SFs)、四环素类(TCs)抗生素的净化性能及微生物群落的响应,以运行多年的单层及多层(3层、6层)基质结构的水平潜流入工湿地为对象,分别采用固相萃取-高效液相色谱法和高通量测序来检测抗生素含量和微生物菌落结构,分析对比分层结构湿地系统中3类8种抗生素的去除规律、对常规污染...     

潜流型菖蒲人工湿地不同C/N对污染物的去除效率

选取炉渣和砾石为基质,以无植被为对照,分别设置低、中、高浓度的3个碳水平(C1、C2、C3)和3个氮水平(N1、N2、N3)处理,研究潜流型菖蒲人工湿地在不同C/N下净化生活污水中COD、总氮(TN)、总磷(TP)的效果。结果表明,在不同C/N下,菖蒲人工湿地对污水中COD、TN的去除效果显著高于无植被的人工湿地,菖蒲植被能增加人工湿地COD去除率10.53%,增加TN去除率6.73%;而对于TP的去除,有无植被无显著差异。随着进水N、P浓度及C/N的变化,菖蒲湿地对COD、TN和TP的去除率分别为67.57%～75.85%、20.91%～56.82%和7.15%～17.78%;同时,菖蒲植株对N、P的积累量也相应的变化,其地上部的N、P积累量为4.44～14.79和1.11～3.37g.m-2,平均占湿地N、P去除率的6.91%和10.67%;地下部的N、P积累量分别为2.35～5.20和0.74～1.41g.m-2,平均占湿地N、P去除率的2.69%和6.02%。植物地上器官对湿地N、P的积累量大于地下部,有利于通过收割作用去除湿地系统中的N、P。     

Effect of mosquitofish (Gambusia affinis) and sestonic food abundance on the invertebrate community within a constructed treatment wetland

1. The effect of mosquitofish (Gambusia affinis) predation on the invertebrate community in a hypereutrophic constructed treatment wetland in southern California was investigated at two nutrient levels that influenced sestonic food abundance. 2. Gambusia affinis and insect predators in the wetland had a significant impact on larval mosquito density in the wetland irrespective of nutrient level. At the end of the 5‐month study, cladoceran abundance in predator exclusion enclosures was 2–3 orders of magnitude greater than in the treatments that allowed access by planktivores. Chironomids were the most abundant insect group collected in emergence traps, and midge production from the high nutrient location of the wetland was greater than from the low nutrient location, but was not affected significantly by G. affinis. The presence of abundant alternative prey in this highly enriched wetland may have weakened the predation impact of G. affinis on mosquitoes. 3. The abundances of six invertebrate groups in dipper samples and of four insect groups in emergence trap collections were analysed using a multivariate distance‐based linear model. Fish treatment and location interactions with sampling date explained significant amounts of the variation in the abundance of invertebrate groups. 4. Multivariate multiple regression analysis showed that chlorophyll‐a concentration explained a large portion of the variability in non‐predatory insect and zooplankton abundance at the high nutrient location, whereas bacterial density explained a large portion of the variability in the abundances of these taxa at the low nutrient location. Predatory insects were not directly coupled to the bottom‐up influence of bacterial abundance and chlorophyll‐a.     

Biodiversity and water quality variations in constructed wetland of Yongding River system

This research was carried on in constructed wetlands of Guan-Ting Reservoir, Beijing, China, from 2004 to 2005. The phytoplankon community was composed of 8 divisions (94 species, including genus and varieties) and the average cell density was 980.93× 10⁴ cells per liter. The dominant divisions were Chlorophyta (36.8%), Bacillariophyta (31.0%) and Cyanophyta (23.4%). The removal rate of phytoplankton density was 72.7%. There was a positive linear correlation between phytoplankon density and total phosphorus. Here, 7 families (13 species) of aquatic vasular plants were found, which constituted emerging and submerging macrophyte communities. In the wetland system, the zooplankton community consisted of Protozoa, Rotifera, Cladocera and Copepoda (70 species). The average density was 4883 individuals per liter. Protozoan and Rotifera were the dominant groups and the removal rate of their density was 81.9%. The correlation between zooplankton and phytoplankton presented a quadratic curve. Also, the zoobenthos community contained Olisochaeta, Uniramia, Crustacea and Mollusca (15 species). The average density was 5670 individuals per m² (62.3% was Uniramia) and the removal rate of their density was 92.4 %. The wetland system reduced COD_Mn, BOD₅, TN, NH_3-N, NO_3-N, TP (total phosphor), PO_4-P and SS in the water of Yong Ding River at 52.9%–99.1%.     

Biodiversity and water quality variations in constructed wetland of Yongding River system

This research was carried on in constructed wetlands of Guan-Ting Reservoir, Beijing, China, from 2004 to 2005. The phytoplankon community was composed of 8 divisions (94 species, including genus and varieties) and the average cell density was 980.93× 10⁴ cells per liter. The dominant divisions were Chlorophyta (36.8%), Bacillariophyta (31.0%) and Cyanophyta (23.4%). The removal rate of phytoplankton density was 72.7%. There was a positive linear correlation between phytoplankon density and total phosphorus. Here, 7 families (13 species) of aquatic vasular plants were found, which constituted emerging and submerging macrophyte communities. In the wetland system, the zooplankton community consisted of Protozoa, Rotifera, Cladocera and Copepoda (70 species). The average density was 4883 individuals per liter. Protozoan and Rotifera were the dominant groups and the removal rate of their density was 81.9%. The correlation between zooplankton and phytoplankton presented a quadratic curve. Also, the zoobenthos community contained Olisochaeta, Uniramia, Crustacea and Mollusca (15 species). The average density was 5670 individuals per m² (62.3% was Uniramia) and the removal rate of their density was 92.4 %. The wetland system reduced COD_Mn, BOD₅, TN, NH_3-N, NO_3-N, TP (total phosphor), PO_4-P and SS in the water of Yong Ding River at 52.9%–99.1%.     

季节性温度变化对CANON型潮汐流人工湿地脱氮的影响

探究了温度的季节性变化对基于亚硝化的全程自养脱氮(CANON)型潮汐流人工湿地(TFCW)脱氮性能及其微生物特性的影响。CANON型TFCW中的脱氮微生物群落在温度的季节性变化下会发生不同程度的改变,其脱氮途径及性能随之会出现周期性的波动。填料层温度在20.0 ℃以上时对TFCW脱氮性能及其中的优势脱氮菌群无显著影响,CANON作用是系统脱氮的主要途径。当填料层温度低于20.0 ℃时,厌氧氨氧化菌丰度与活性显著降低,在9.3~20.0 ℃时,亚硝酸盐氧化菌(NOB)的增殖及其活性的提高使TFCW中脱氮的主要途径由CANON作用演替为硝化/反硝化作用,系统对总氮(TN)的去除率仅为(34.8±13.0)%;在2.2~9.0 ℃时,TFCW中的厌氧氨氧化菌在受到抑制的同时仍保持着对NOB和反硝化菌群的相对竞争优势,系统脱氮重新依赖于CANON作用,其对TN的去除率为(54.8±4.8)%。该研究可为CANON型TFCW工艺的优化及工程化应用提供参考。     

长江安庆段河流湿地生态系统呼吸及其影响因子

研究湿地生态系统呼吸(Reco)对评价湿地生态系统碳汇功能具有重要的意义.采用涡度相关法对位于长江中游河流湿地的杨树人工林生态系统进行了长期的定位观测,根据2005-07-23～2007-12-15的数据对Reco进行估算,并分析Reco对主要环境因子的响应特征.结果表明:(1)Reco具有明显的季节变化,每年的最大值出现在8月份,最小值出现在1月份,Reco受空气温度、土壤温度和土壤含水量共同影响,总体上看空气温度是驱动Reco的主要因子;(2)在几种模拟生态系统呼吸的模型中,Van't Hoff方程、Arrhenius方程、Lloyd-Talor方程在统计意义上具有同等的能力,由空气温度和土壤含水量共同驱动的连乘模型对Reco的拟合效果最好;(3)使用连乘模型估算的2006年生态系统呼吸总量为1074.7 gC·m-2·a-1,2007年为1127.0 gC·m-2·a-1,与亚热带和温带的森林站点的测定值相接近.