短程硝化反硝化工艺处理低C/N餐厨废水

针对餐厨废水的水质特点,提出低C/N下的短程硝化反硝化餐厨废水处理组合工艺。通过控制微氧区、好氧区DO分别为0.5 mg/L和2.5 mg/L;硝化液,微氧区混合液和污泥回流比分别为200%、100%和100%,可以实现NO-2-N累积率达到90%以上,COD、氨氮平均去除率为73.42%和98.57%。较低的C/N使得反硝化效果不佳,对反应器进水补充适量的甲醇作为碳源,在COD/TN约为4的情况下,以NO-2-N为主的反硝化可以使反应器对TN的去除率达到94%,出水各项指标符合相关排放标准,实现了餐厨废水高效和经济的生物脱氮。     

一株耐盐好氧反硝化细菌的分离鉴定及其脱氮特性

从处理高盐废水的生物接触氧化工艺成熟活性污泥中分离得到一株耐盐好氧反硝化细菌F10.根据形态学特征、生理生化以及16S rRNA基因序列测定分析,初步判定该菌株为盐单胞菌属(Halomonas sp.).菌株能在盐度为3%~7%的培养基中良好的生长及脱氮,最适盐度为3%(以Na Cl计),最适碳源为乙酸钠,最适p H为7~8,最适温度为30℃.该菌株能利用NO-3-N进行反硝化作用,在盐度为3%的反硝化培养基中24 h内对NO-3-N的去除率达到92.6%,36 h基本完全去除。该菌株在3%盐度下表现出良好的异养硝化-好氧反硝化性能,初始硝态氮浓度在270 mg/L时,菌株的脱氮率可达90%以上,氨氮的去除率可达75%以上,脱氮过程中无NO-2-N积累,可实现同步硝化反硝化,具有一定的工程应用价值。     

C/N比对ANAMMOX与反硝化协同脱氮性能影响及其动力学

采用ASBR厌氧氨氧化(ANAMMOX)反应器,考察了不同C/N(NH+4-N)比时厌氧氨氧化与反硝化协同脱氮性能表现,并与无机环境下反应器的脱氮性能相比较。研究结果表明,C/N比决定了ANAMMOX/反硝化耦合反应的发展方向。当C/N0.33时,ANAMMOX为主导反应;当C/N=0.67时,耦合反应的效果最佳,NH_4~+-N和NO_2~--N的去除率分别为92%、95%、COD去除率大于96%,实现了氨氮及COD的同时去除;当C/N=1.33时,反硝化反应逐渐占据优势;当C/N2.96时,反硝化作用成为主导反应,厌氧氨氧化反应受到明显抑制,氨氮去除率下降。采取批次实验方法研究了厌氧氨氧化与反硝化协同反应的动力学特性。用基质抑制动力学Haldane模型拟合不同基质浓度下的厌氧氨氧化活性,得到氨氮最大比增长速率为0.09 kg/(kg·d)(以VSS计),半饱和常数为8.4 mg/L、半抑制常数为1 198.2 mg/L;亚硝态氮最大比增长速率为0.27 kg/(kg·d)(以VSS计),半饱和常数为10.2 mg/L、半抑制常数为300.1 mg/L。采用Monod模型和Haldane模型分别拟合不同COD浓度和亚硝酸盐浓度下的反硝化性能,得到反硝化亚硝态氮最大比增长速率为0.2 kg/(kg VSS·d),半饱和常数为17.4 mg/L、半抑制常数为128.4 mg/L,COD半饱和常数为83.3 mg/L。     

MFC强化同步短程硝化反硝化工艺的启动

微生物燃料电池(MFC)可在阴极实现反硝化、短程反硝化和同步硝化反硝化并产生电能,但在MFC阴极实现同步短程硝化反硝化的研究尚未见到报道。为了探讨MFC阴极同步短程硝化反硝化工艺的性能,将双室曝气阴极MFC与A/O脱氮工艺结合处理人工模拟低碳氮比废水。通过静置运行15 d使得MFC阴极室亚硝态氮得以积累,氨氧化菌得以富集。随即改为连续运行后第21天成功启动同步短程硝化反硝化MFC;阴极出水氨氮浓度为0.3 mg/L,亚硝态氮浓度为15.9 mg/L,硝态氮浓度为0.6 mg/L,亚硝化率达到95%以上,阴极电极自养反硝化去除率达到50%以上,COD去除率达到85%以上。结果表明,将MFC与同步短程硝化反硝化工艺结合,通过阴极室中氧气得电子获得高p H,可以强化同步短程硝化反硝化工艺,完成生物脱氮的同时回收电能,并具有减少外加碱度的优势。     

高有机物浓度下氨氮的好氧硝化

污水中往往同时含有较高浓度的有机物和氨氮,研究较高有机物浓度下氨氮的好氧生物硝化,以为工程应用提供实践和理论依据。考察了COD浓度为1 200 mg·L~(-1),好氧活性污泥处理氨氮废水过程中COD、NH_4~+-N的去除情况,硝态氮、亚硝态氮的生成情况。在整个驯化阶段,氨氮的最高去除率达到86.42%,COD最高去除率达到85.40%,同时亚硝态氮的最大生成量为15.97 mg·L~(-1),硝态氮的最高生成量为5.14 mg·L~(-1),且8 h的短期实验显示,COD、NH_4~+-N的去除可以同步进行。     

污水中不同COD组分下A/O脱氮工艺的反硝化效率

为了研究了不同COD组分进水对A/O工艺中反硝化的影响以及COD组分中溶解性易生物降解COD(SS)、颗粒性慢速可生物降解COD(XS)比例改变后系统反硝化速率和反硝化潜力的变化。以连续流A/O反应器脱氮效率为研究对象,通过改变碳源物质投配量来配置3种SS比例分别为15%、30%和50%的城市污水,系统地考察了进水中SS比例对反硝化的影响。结果表明,进水中SS比例由15%增加到50%后,可以明显提高A/O系统TN的去除率,脱氮率由82%提高到89%。同时通过缺氧反硝化间歇实验,从反硝化动力学角度分析,进一步确定进水中SS比例对反硝化速率和反硝化潜力的影响,发现进水SS比例分别为50%、30%和15%,系统反硝化速率分别为0.027 g NO-3-N/(g VSS·min)、0.022 g NO-3-N/(g VSS·min)和0.020 g NO-3-N/(g VSS·min),反硝化潜力分别为16.49、13.99和13.74 mg/L。可见随着进水中SS比例的升高,系统中反硝化速率和反硝化潜力也相应增加。得出进水中COD组分不同,尤其是SS所占比例大小,是影响反硝化效果的一个关键因素。     

活性炭海绵动态膜生物反应器处理生活污水的研究

采用序批式活性炭海绵基材动态膜生物反应器处理模拟生活污水。在反应周期为6 h,好氧、厌氧时间比为2∶1,处理水量为18 L的条件下,讨论反应器及动态膜分别对COD、TN、NH3-N、TP的去除效果,并分析反应器中氮的去除机理。结果表明:活性炭海绵基材动态膜生物反应器对COD、TN、NH3-N和TP平均去除率分别为97.99%、84.24%、95.52%和78.94%,动态膜对COD、TN、NH3-N和TP平均去除率为8.96%4、.75%、1.30%和7.54%;好氧结束时,反应器中的氮主要以硝态氮形式存在,浓度稳定在16 mg/L左右,出水中的硝态氮和亚硝态氮平均含量相近,分别为4.10 mg/L和3.69 mg/L;滤饼层对浊度有很好的去除效果,稳定运行时出水浊度可降至2 NTU以下。     

微电解强化微生物菌种对高氨氮低碳氮比黑臭水的脱氮研究

针对高氨氮低碳氮比(C/N)黑臭水进行脱氮研究,通过硝化菌和反硝化菌共同作用,并在后期耦合铁碳微电解(IC-ME)强化脱氮。单因素控制变量实验表明,硝化菌和反硝化菌在30℃硝化/反硝化效果较优,平均氨氮去除率为71.62%,硝态氮去除率可达到67.52%;在溶解氧(DO)为3 mg/L时硝化效果较好,平均氨氮去除率达到了70.08%;在后期投加150 g/L铁碳填料时,反硝化效果最好,2#和3#反应器硝态氮去除率最高分别提高到了81.78%和91.17%。长时间运行反应器后,氨氮去除负荷达到0.193 kg/(m³·d),化学需氧量(COD)去除负荷达到1.786 kg/(m³·d)。单独的微生物菌种针对高氨氮低C/N黑臭水脱氮还有一定的局限性,通过后期耦合IC-ME,脱氮效率明显提升,总氮(TN)去除率可从45.65%提升到58.91%。     

异养硝化-好氧反硝化菌ADN-42的脱氮特性

从大连海域典型繁茂膜海绵(Hymeniacidon perleve)中筛选出1株耐盐异养硝化-好氧反硝化菌,通过形态观察、生理生化实验和16S rRNA基因序列分析,确定其为假单胞菌属(Pseudomonas),命名为ADN-42。其异养硝化-好氧反硝化条件为氯化铵为氮源,柠檬酸三钠为碳源,温度30℃,C/N值为12,摇床转速150 r/min,NH+4-N初始浓度约300 mg/L,盐度为40 g/L Na Cl,在此条件下菌株84 h时NH+4-N去除率为75.4%,无硝态氮产生,亚硝态氮最大积累量为8.3 mg/L;将菌株投加到NH+4-N和NO-2-N混合体系中,混合系统比仅以NH+4-N为氮源的体系的NH+4-N去除速率提高了12.7%;研究结果表明Pseudomonas sp.ADN-42可能是一株有着良好应用前景的高效耐盐异养硝化-好氧反硝化菌。     

反硝化生物滤池用于再生水脱氮效能及动力学研究

采用反硝化生物滤池处理城市污水厂二级出水,研究了反硝化生物滤池脱氮效能及其影响因素,构建了反硝化生物滤池脱氮动力学模型。结果表明,反硝化生物滤池启动7d后出水水质稳定,对NO-3-N的去除率达到90%以上,NO-2-N积累现象消失;当外加乙酸钠作碳源并使C/N≥4.7时,对NO-3-N的去除率达到90%以上,出水NO-3-N浓度在1.0mg/L以下;反硝化生物滤池具有较高的处理负荷,当HRT≥5 min时,对NO-3-N的去除率能达到90%以上;在实验水质条件下,滤池反硝化反应遵循一级反应动力学,且反应速率常数与流速成正比。     

Chloroaromatic pollutants in mussels incubated in two finnish watercourses polluted by industry

Concentrations of different chlorinated compounds were measured in mussels incubated in two polluted watercourses, a river (the River Kymijoki) and a lake (Lake Vanaja) for four weeks in summer 1995. The sum concentrations of polychlorinated phenols (PCP) and biphenyls (PCB) were both about 1 μg/g lipid weight (lw) in Lake Vanaja mussels, while in the River Kymijoki mussels PCPs were non-detectable and PCBs were measured 120 ng/g lIw. The concentrations of toxic polychlorinated dibenzo-p-dioxin (PCDD) and dibenzofuran (PCDF) congeners ranged between <17 and 370 pg/g Iw in Lake Vanaja mussels and between <38 and 11,000 pg/g lw in the River Kymijoki mussels. Polychlorinated diphenyl ethers (PCDE) were detected in the mussels incubated in the River Kymijoki (0.4–1.1 ng/g Iw), but not in those incubated in Lake Vanaja. Polychlorinated phenoxyanisoles (PCPA) were measured 33 ng/g lw and polychlorinated phenoxyphenols (PCPP) 300 ng/g lw in the mussels incubated in the River Kymijoki. PCPAs were also detected in reference samples, which were sediment and pike from the River Kymijoki and Baltic salmon, seal and white-tailed sea eagle.     

Book review

The Pesticide Manual ‐ A World Compendium, 8th Edition, C.R. Worthing, Editor and S.B. Walker, Assistant Editor, British Crop Protection Council, BCPC Publications Sales, Bear Farm, Binfield, Bracknell, Berkshire RG12 5QE, England. 1987, 1100 pp., UK £50; Overseas £56. ISBN 0–948404–01–9.     

Organochlorine compounds in a three-step terrestrial food chain

The concentrations of 15 organochlorine chemicals (PCBs and pesticides) were studied in a Central European oak wood food chain system: Great tit (Parus major), caterpillars (Tortrix viridana, Operophtera brumata, Erannis defoliaria), and oak-leaves (Quercus robur). Juvenile tits receive organochlorines from the mother via egg transfer and, eventually to a greater extent, from the caterpillar food source during nestling period. The concentrations of PCB 153 (2,2′,4,4′,5,5′-hexachlorobiphenyl, the most abundant in this study) was found in leaf material at ca. 1 ng/g, in caterpillars 10 ng/g, and in bird eggs 170 ng/g on an average and on a dry mass basis.     

The chemical stability of formulations of some hydrolyzable insecticides in aqueous mixtures with hydrolysis catalysts

Abstract

The active ingredients in commercial formulations of malathion, oxamyl, carbaryl, diazinon, and chlorpyrifos diluted to “spray tank”; concentrations with buffered distilled or natural water of pH 4–9 were stable for at least 24 hr. Formulations of trichlorfon were not stable at pH 7 or above but disappearance rates were slower than for the pure chemical in homogeneous solution. Cupric ion was observed to be an effective catalyst for the hydrolysis of a variety of pure organophosphorus insecticides but did not catalyze hydrolysis of the active ingredients of the formulations examined. Increasing the dilution of the formulation increased the susceptibility of malathion, oxamyl, and carbaryl to hydrolysis.     

Radionuclides in pinon pine (Pinus edulis) nuts from los alamos national laboratory lands and the dose from consumption

Abstract

One of the dominant tree species growing within and around the eastern portion of Los Alamos National Laboratory (LANL), Los Alamos, NM, lands is the pinon pine (Pinus edulis). Pinon pine is used for firewood, fence posts, and building materials and is a source of nuts for food—the seeds are consumed by a wide variety of animals and are also gathered by people in the area and eaten raw or roasted. This study investigated the (1) concentration of ³H, ¹³⁷Cs, ⁹⁰Sr, ^totU, ²³⁸Pu, ^{239, 240}Pu, and²⁴¹ Am in soils (0‐ to 12‐in. [31 cm] depth underneath the tree), pinon pine shoots (PPS), and pinon pine nuts (PPN) collected from LANL lands and regional background (BG) locations, (2) committed effective dose equivalent (CEDE) from the ingestion of nuts, and (3) soil to PPS to PPN concentration ratios (CRs). Most radionuclides, with the exception of ³H in soils, were not significantly higher (p < 0.10) in soils, PPS, and PPN collected from LANL as compared to BG locations, and concentrations of most radionuclides in PPN from LANL have decreased over time. The maximum net CEDE (the CEDE plus two sigma minus BG) at the most conservative ingestion rate (10 lb [4.5 kg]) was 0.0018 mrem (0.018 μSv); this is far below the International Commission on Radiological Protection (all pathway) permissible dose limit of 100 mrem (1000 μSv). Soil‐to‐nut CRs for most radionuclides were within the range of default values in the literature for common fruits and vegetables.     

Degradation and sorption of imidacloprid in dissimilar surface and subsurface soils

Degradation and sorption/desorption are important processes affecting the leaching of pesticides through soil. This research characterized the degradation and sorption of imidacloprid (1-[(6-chloro-3-pyridinyl)-methyl]-N-nitro-2-imidazolidinimine) in Drummer (silty clay loam) and Exeter (sandy loam) surface soils and their corresponding subsurface soils using sequential extraction methods over 400 days. By the end of the incubation, approximately 55% of imidacloprid applied at a rate of 1.0 mg kg^?1 degraded in the Exeter sandy loam surface and subsurface soils, compared to 40% of applied imidacloprid within 300 days in Drummer surface and subsurface soils. At the 0.1 mg kg^?1 application rate, dissipation was slower for all four soils. Water-extractable imidacloprid in Exeter surface soil decreased from 98% of applied at day 1 to > 70% of the imidacloprid remaining after 400 d, as compared to 55% in the Drummer surface soil at day 1 and 12% at day 400. These data suggest that imidacloprid was bioavailable to degrading soil microorganisms and sorption/desorption was not the limiting factor for biodegradation. In subsurface soils > 40% of ¹⁴C-benzoic acid was mineralized over 21 days, demonstrating an active microbial community. In contrast, cumulative ¹⁴CO₂ was less than 1.5% of applied ¹⁴C-imidacloprid in all soils over 400 d. Qualitative differences in the microbial communities appear to limit the degradation of imidacloprid in the subsurface soils.     

Biochemical interaction of six op delayed neurotoxicants with several neurotargets

Abstract

Five organophosphorous insecticides: Leptophos, EPN, Cyano‐fenphos, trichloronate and salithion proved to cause irreversible ataxia not only to chicken but also to mice and sheep. TOCP was included as a reference. Cyanofenphos blocked the catecholamine B‐receptor binding activity with ³H‐norepinephrine at a level similar to that of the specific inhibitor propranolol in the mouse heart preparation. In the lamb heart preparation, the B‐receptor was more sensitive to Leptophos, salithion and TOCP than to propranolol. The six compounds and their oxons were screened for their in‐vitro inhibition to monamine oxidase (MAO), acetyl cholinesterase (AChE) and neurotoxic esterase (NTE) in the brain of either mouse, lamb or chicken. It is believed that their AChE inhibition stands for their acute toxicity, while NTE inhibition is responsible for their paralytic ataxia.     

土壤中砷的化学平衡

本文比较详细地综述了砷的化学特性,环境背景值及来源和循环,土壤中砷的三大化学平衡即沉淀溶解平衡,氧化还原平衡,吸附解吸平衡,以及微生物对砷的转化。     

Elemental uptake by edible herbs and lettuce (Latuca sativa)

The total concentration of toxic elements (aluminum, cadmium, chromium and lead) and selected macro and micro elements (iron, manganese, copper and zinc) are reported in six leafy edible vegetation species, namely lettuce, spinach, cabbage, chards and green and red types of Amaranth herbs. Although spinach and chards had greater than 125 mv of iron, both the amaranthus herbs recorded > than 320 μ g g^{? 1} dry weight. In both the spinach and chard species, the Mn and Zn levels were appreciable recording > 225 μ g g^{? 1} and 150 μ g g^{? 1} dry weight, respectively. Aluminum concentrations were (in μ g g^{? 1} dry weight) lettuce (10), cabbage (11), spinach (167), chards (65), amaranthus green (293) and amaranthus red (233). All the micro and macro elements and the toxic elements (Ni, Cr, Cd and Pb) elements analyzed, were below the recommended maximum permitted levels (RMI) in vegetables. Further the elemental uptake and distribution of the nine elements, at three growth stages of the lettuce plant grown on soil bed under controlled conditions are detailed. In the soil, except for iron (16%), greater than 33% of the other cations were in exchangeable form. Generally in the lettuce plant, roots retained much of the iron (> 224 μ g g^{? 1}) and aluminum (> 360 μ g g^{? 1}), while leaves had less than 200 μ g g^{? 1} of iron and 165 μ g g^{? 1} of Al. Although the concentrations of elements marginally decreased with growth, the lettuce leaves had significant amounts of Mn (30 μ g g^{? 1}), Zn (50 μ g g^{? 1}) and Cu (3.6 μ g g^{? 1}). Some presence of lead in leaves (2.0 μ g g^{? 1}) was noticed, but all the toxic and other elements analyzed were well below the RMI values for the vegetables.     

The dissipation of nonlyphenol in stream and pond water under simulated field conditions

Abstract

The dissipation of 1.0 ppm nonylphenol in stream and pond water, incubated in flasks at 16°C under simulated field conditions up to 44 days indicated that the half‐life was 2.5 days if the flasks were open, and 16 days if they were closed. A transformed product was detected in the closed flasks.

Translocation of nonylphenol in water occurred when treated water samples were incubated in the presence of sediment. After 10 days, nonylphenol was detected only in the sediment, but not in water (detection limit = 10 ppb). About 80% of the nonylphenol was degraded in 71 days, but no degradation occurred if the water and the sediment were autoclaved prior to incubation.