序批式反应器用于牛场污水的处理

对序批式反应器 (SBR)用于牛场污水的处理进行了试验研究 ,主要研究了三个水力停留时间 (HRT)和有机负荷率对污染物去除率、出水水质和污泥特性的影响。试验结果表明 ,对 10 0 0 0mg/LCOD牛场污水 ,使用 1dHRT ,相应有机负荷率为 10gCOD/L·d时 ,混合出水COD、TS、VS、TKN和TN的去除率分别为 45 %、2 1.4%、34 .2 %、5 3.2 %和 2 2 .2 % ,上清液出水的分别为 80 .2 %、6 3.4%、6 6 .2 %、75 %和 38.3% ;两种出水的SCOD和NH3 N去除率相同 ,分别为 5 0 .0 %和 76 .5 %。经SBR处理后 ,污泥的沉降浓缩性能也有了比较明显的改善。     

序批式生物膜法同步除磷脱氮特性研究

对淹没序批式生物膜法去除有机物和磷及同步部分脱氮的特性进行了研究。其适合的载体装填密度为30％，水力停留时间为9h，其中厌氧3h，好氧6h，进水COD负荷从0．27kg/(m^3.d)到1．32kg/(m^3.d)均可使除磷率达90％以上，脱氮率达50％－60％。淹没式生物膜法除磷脱氮工艺中的优势菌属为假单胞菌属，其次依顺序为气单胞菌属，芽孢杆菌属，微球菌属，硝化矸菌属，生物膜具有生物量大（MLVSS达5531．7mg/L)，脱落污泥含磷量高（达5．67％），沉降性好（SVI为101．7）的特点，污泥产率为0．1996kg干泥／kgCOD。     

Mechanism studies on nitrogen removal when treating ammonium-rich leachate by sequencing batch biofilm reactor

The nitrogen removal mechanism was studied and analyzed when treating the ammonium-rich landfill leachate by a set of sequencing batch biofilm reactors (SBBRs), which was designed independently. At the liquid temperature of (32 ± 0.4)°C, and after a 58-days domestication period and a 33-days stabilization period, the efficiency of ammonium removal in the SBBR went up to 95%. Highly frequent intermittent aeration suppressed the activity of nitratebacteria, and also eliminated the influence on the activity of anaerobic ammonium oxidation (ANAMMOX) bacteria and nitritebacteria. This influence was caused by the accumulation of nitrous acid and the undulation of pH. During the aeration stage, the concentration of dissolved oxygen was controlled at 1.2–1.4 mg/L. The nitritebacteria became dominant and nitrite accumulated gradually. During the anoxic stage, along with the concentration debasement of the dissolved oxygen, ANAMMOX bacteria became dominant; then, the nitrite that was accumulated in the aeration stage was wiped off with ammonium simultaneously. Translated from Acta Scientiae Circumstantiae, 2006, 26(1): 55–60 [译自: 环境科学学报]     

Factors affecting simultaneous nitrification and denitrification in an SBBR treating domestic wastewater

An aerobic sequencing batch biofilm reactor (SBBR) packed with Bauer rings was used to treat real domestic wastewater for simultaneous nitrification and denitrification. The SBBR is advantageous for creating an anoxic condition, and the biofilm can absorb and store carbon for good nitrification and denitrification. An average concentration of oxygen ranging from 0.8 to 4.0 mg/L was proved very efficient for nitrification and denitrification. Volumetric loads of TN dropped dramatically and effluent TN concentration increased quickly when the concentration of average dissolved oxygen was more than 4.0 mg/L. The efficiency of simultaneous nitrification and denitrification (SND) increased with increasing thickness of the biofilm. The influent concentration hardly affected the TN removal efficiency, but the effluent TN increased with increasing influent concentration. It is suggested that a subsequence for denitrification be added or influent amount be decreased to meet effluent quality requirements. At optimum operating parameters, the TN removal efficiency of 74%–82% could be achieved. Translated from Acta Scientiae Circumstantiae, 2006, 26(5): 728–733 [译自: 环境科学学报]     

SBBR工艺的现状与发展

序批式生物膜反应器(SBBR)是目前正在研究、应用的一种污水生物处理新工艺，它是在SBR的基础上发展起来的，既保留了SBR的诸多优点，又有不同于SBR的特点。由于SBBR工艺的脱氮除磷效果好，自动化程度高，运行管理简单，基建费用低，运行费用省，推广到城市污水处理中，必将产生良好的环境效益和社会效益，其应用前景十分广阔。     

曝气生态滤池中微生物群落组成及物种多样性

为研究曝气生态滤池滤料表面物种多样性及其净水机理,通过高通量测序和生物信息分析对曝气生态滤池（EAF）中2种填料的不同DO区域微生物丰度和多样性进行研究和分析.结果表明,在EAF运行过程中,变形菌门所占比例均在71%以上,具有绝对优势,优势菌群的大量增殖使装置具有较高的TN去除率（67%）,其中好氧区海绵铁表面样本优势菌群比例最高,达到77.49%,表明海绵铁在曝气条件下更适合优势菌群变形菌门的繁殖;Alpha多样性分析发现EAF内填料表面生物膜中微生物菌落丰度均高于空白样,表明EAF较自然环境更适合微生物生长;Beta多样性分析发现装置由于曝气使优势菌群变形菌门在填料表面大量繁殖,限制了其他菌种繁殖,虽然生物多样性略有降低,但随着优势菌群大量增殖从而提升了对TN的去除能力.     

Linkage between water soluble organic matter and bacterial community in sediment from a shallow, eutrophic lake, Lake Chaohu, China

Lacustrine sediment played important roles in migration and transformation of its water soluble organic matter (WSOM), and the source and composition of WSOM would affect water trophic status and the fate of pollutants. However, we know little about the pathway of WSOM transformation and its driving bacterial communities in lacustrine sediment. In the present study, we investigated the spatial distribution patterns of sediment WSOM and its fluorescent fractions across Lake Chaohu using fluorescence spectroscopy, and explored WSOM compositional structure through our proposed calculated ratios. In addition, we also analyzed sediment bacterial community using Illumina sequencing technology, and probed the possible pathway of sediment WSOM transformation under the mediate of indigenous bacteria. Our results showed that the inflowing rivers affected the spatial distribution patterns of WSOM and its five fractions (including tyrosine-, tryptophan-, fulvic acid-, humic acid-like substances and soluble microbial productions), and sediment WSOM originated from fresh algae detritus or bacterial sources. In parallel, we also found that Proteobacteria (mainly γ-Proteobacteria and δ-Proteobacteria), Firmicutes (mainly Bacilli), Chloroflexi, Acidobacteria, Planctomycetes and Actinobacteria dominate sediment bacterial community. Furthermore, these dominant bacteria triggered sediment WSOM transformation, specifically, the humic acid-like substances could be converted into fulvic acid-like substances, and further degraded into aromatic protein-like and SMP substances. In addition, our proposed ratios (P-L:H-L, Ar-P:SMP and H-L ratio), as supplementary tool, were effective to reveal WSOM composition structure. These results figured out possible pathway of WSOM transformation, and revealed its microbial mechanism in lacustrine sediment.     

寒旱区湖泊沉积物中固氮微生物群落特征——以包头南海湖为例

为了探究寒旱区湖泊中固氮菌的地区差异性,利用固氮菌特异性功能基因nif H对南海湖沉积物中的固氮菌进行测定并分析其与环境因子之间的相互作用关系.结果表明：不同湖区优势固氮菌群落组成存在差异,整体上由3门（蓝藻门、厚壁菌门、变形菌门）10属（蓝藻菌属、着色菌属、梭菌属、鱼腥藻属、红螺菌属、厌氧粘细菌属、荚硫菌属、柱孢藻属、根瘤菌属、假单胞菌属）组成;寒旱区特有的冰封期长、紫外线照射强等环境条件导致沉积物中的主导固氮菌为蓝藻门下的微生物.冗余分析结果表明：较高的C/N和TP是固氮菌生存的必要营养条件,可以促进固氮反应的顺利进行,较高的TN和NH₃-N含量及较低的pH值会抑制表层沉积物部分固氮微生物的生长,较高的pH值尤其会抑制鱼腥藻属、荚硫菌属、蓝藻菌属、红螺菌属的生长.本研究通过探讨寒旱区固氮微生物在沉积物中的分布来研究固氮作用的潜在功能,进一步补充其在氮循环中的重要作用.     

C/N对SBR生物脱氮硝化过程微生物结构的动态影响

为揭示碳氮比（C/N）对硝化过程影响的机理本质,试验以人工模拟废水为研究对象,采用4组平行的SBR（R₀、R₅、R₁₀、R₁₅）反应器,基于16S rRNA基因-Illumina MiSeq高通量测序技术,考察了4种C/N（0、5、10、15）对硝化过程功能微生物组成和结构特征的影响.结果表明：4种C/N条件下,系统均获得了较好的去除氨氮（去除率>95%）和COD（去除率>90%）效果,TN也有不同程度的降低.此外,C/N会显著影响系统内微生物的多样性、种群结构和功能.R₀系统Chao1指数（922）、ACE指数（1232.4）、Shannon指数（6.76）和Simpson指数（0.96）均最大,故微生物多样性最丰富,而R₅的物种丰富度最低.在微生物门水平上,变形菌门（Proteobacteria）、拟杆菌门（Bacteroidetes）、蓝细菌门（Cyanobacteria）等9个相对丰度较高的门是重要的微生物门,其中变形菌门（Proteobacteria）约全部微生物的40.7%~65.2%,是4个系统中最优势的菌门.硝化过程的关键菌群亚硝化单胞菌科（Nitrosomonadaceae）及硝化螺旋菌属（Nitrospira）的相对丰度表现出随着C/N升高而急剧降低的趋势.基于LEfSe分析共获得了34组具有显著差异的微生物,从而得到了每种C/N条件下在微生物学分类水平上的菌群关键生物标记物.     

碳添加对土壤固碳细菌群落结构及多样性的影响——以松嫩平原盐碱耕地为例

采用高通量测序技术,研究秸秆、生物炭和纳米碳3种碳源添加对盐碱耕地土壤固碳细菌群落结构及多样性的影响,并分析土壤化学性质与固碳细菌群落多样性的关系.结果表明：3种碳源添加均降低土壤固碳细菌群落多样性,其中生物炭和纳米碳添加的土壤固碳细菌的Chao1指数、物种多样性、Shannon指数及系统多样性值均高于秸秆添加的.3种碳源添加均降低土壤固碳细菌群落的物种丰度,其中纳米碳添加的物种丰度大于秸秆和生物炭添加的.在群落组成方面及相对丰度上,3种碳源添加后的优势菌门为变形菌门（Proteobacteria）,优势菌纲为γ-变形菌纲（Gammaproteobacteria）,均在纳米碳添加后相对丰度最高,分别为90.38%、57.79%.群落组间差异分析结果显示,秸秆和纳米碳添加后土壤固碳细菌群落结构差异显著.冗余分析结果表明,土壤固碳细菌群落结构受土壤pH值、有机碳、全氮、全磷、碱解氮及有效磷的综合影响,其中土壤pH值和有效磷含量是影响土壤固碳细菌群落结构的主要化学性质.综合来看,在盐碱耕地中添加秸秆、生物炭或纳米碳,都抑制了土壤固碳细菌群落的多样性和物种丰度,但纳米碳能够增加土壤固碳细菌群落结构差异.