Sludge concentration dynamic distribution and its impact on the performance of UNITANK

UNITANK is a biological wastewater treatment process that combines the advantages of traditional activated sludge process and sequencing batch reactor, which is divided into Tank A, B and C. In this study, the sludge distribution and its impact on performance of UNITANK were carried out in Liede Wastewater Plant （WWTP） of Guangzhou, China. Results showed that there was a strong affiliation between Tank A and B of the system in sludge concentration distribution. The initial sludge concentration in Tank A could present the sludge distribution of the whole system. The sludge distribution was mainly influenced by hydraulic condition. Unsteady sludge distribution had an impact on variations of substrates in reactors, especially in decisive reactor, and this could lead to failure of system. Settler could partially remove substrates such as COD and NO3-N, but there was adventure of sludge deterioration. The rational initial sludge concentration in Tank A should be 4000-6000 mg/L MLSS.     

卤系阻燃剂在东江工业水体中的质量浓度及其分配特征

本研究分析了东江工业水体中卤系阻燃剂的浓度,组成分布以及分配特征.结果表明多溴联苯醚(PBDEs)是水体中的主要的卤系阻燃剂,占总卤系阻燃剂的41.0%,其质量浓度范围为1 102.3~3 666.9 pg·L~(-1),其中BDE209是颗粒相的主要成分.四溴双酚A(TBBPA)占总卤系阻燃剂的32.4%,其质量浓度范围为1 120.9~2 856.5 pg·L~(-1),其他卤系阻燃剂如十溴二苯乙烷(DBDPE)、德克隆(DP)和六溴环十二烷(HBCDs)分别占总卤系阻燃剂的16.3%、7.3%和3.0%,其质量浓度范围分别为397.7~1 736.8、235.7~778.1和9.5~266.8 pg·L~(-1).在对水体溶解相和颗粒相分配的研究中发现,PBDEs、DBDPE、DP和HBCDs主要存在于水体颗粒相中,而TBBPA由于其较大的水溶性,主要存在于溶解相中;卤系阻燃剂的lgK_(oc)与lgK_(ow)之间存在显著的相关性,但是lgK_(oc)实测值与其理论预测值有一定差异,这可能是受控于悬浮颗粒(SPM)含量和溶解有机碳(DOC)含量这两个因素,此外,颗粒相和溶解相之间分配是否达到平衡也是影响测量lg Koc值的因素.     

稻田灌溉河流CH4和N2O排放特征及影响因素

随着农业氮肥大量施用,大量碳氮营养物质以淋溶或径流形式进入周边灌溉水体,使其成为甲烷(CH4)和氧化亚氮(N2O)的重要排放源.以我国东南部地区典型稻田灌溉河流为研究对象,于2014年9月至2016年9月连续两年原位观测表层水体CH4和N2O溶存浓度及其排放通量,旨在明确稻田灌溉河流CH4和N2O的排放特征、排放强度及其主要驱动因子.结果表明,观测期内c(CH4溶存)的年平均值为(390.57±43.95)nmol·L-1(92.80～1 577.54 nmol·L-1),c(N2O溶存)的年平均值为(40.23±3.20)nmol·L-1(10.05～75.40 nmol·L-1).CH4和N2O的排放通量(年平均)分别为(20.73±6.08)mg·(m2·h)-1和(34.30±7.12)μg·(m2·h)-1.CH4和N2O溶存浓度和排放通量整体上均呈现出春夏排放高,秋冬排放低的季节变化趋势.两年CH4累计排放总量为(3 876.30±1 153.96)kg·hm-2,N2O累计排放总量为(5.74±0.98)kg·hm-2.两者持续性全球增温潜势(SGWP,以CO2-eq计)平均为(87.99±15.73)t·(hm2·a)-1.CH4排放通量与水温、底泥可溶性有机碳(DOC)显著正相关,而与水体溶解氧(DO)显著负相关;N2O排放通量与水温、水中铵态氮(NH4+-N)和硝态氮(NO3--N)显著正相关,而与水体DO显著负相关.该研究可为科学估算我国农业灌溉流域CH4和N2O排放总量提供数据支撑和重要参考.     

反硝化除磷污泥聚集体内原位除磷活性及有机物浓度的影响

以SBR系统反硝化除磷污泥为对象,利用氧化还原电位、溶解氧和磷酸盐微电极定量研究了污泥聚集体内除磷菌的原位除磷活性及有机物浓度的影响.结果发现,厌氧初期污泥聚集体内最大净体积释磷速率为3.29 mg·(cm3? h)-1,是缺氧初期最大净体积吸磷速率的3倍左右;厌氧末期释磷速率明显降低,最大净体积释磷速率仅为厌氧初期的...     

南京城市大气氨-铵的高频演化及其气粒转化机制

本研究于2018年秋季利用在线气体和气溶胶组分监测仪以高时间分辨率连续测定南京市大气中的气体(主要是NH_3)与二次无机气溶胶(主要是NH_4~+、NO_3~-和SO_4~(2-))浓度,借此研究污染和非污染期城市大气NH_3和NH_4~+的演化规律,进而探讨NH_3-NH_4~+气粒转化过程中的化学机制.结果表明,观测期间NH_3和NH_4~+浓度的平均值(±1σ)分别为(15. 3±6. 7)μg·m-3和(11. 3±7. 8)μg·m-3,且日变化在污染和非污染事件中呈现出显著的差异.综合在线观测的NH_3和NH_4~+浓度数据,通过计算潜在源贡献因子,分析了NH_3和NH_4~+的潜在贡献源区在重污染过程受长距离污染传输影响较小,证明城市也是NH_3排放的重要热点地区.进一步分析发现,NH_3-NH_4~+的气粒转化是影响NH_3和NH_4~+日变化的主要驱动因子.具体体现在:低温、高湿(温度在7. 5～12. 5℃,湿度在50%～90%)时,NH_3和NH_4~+的气固转化速度较快,NH_3与酸性物质反应生成更多的NH_4~+,使得(NH4)2SO4和NH4NO3的形成从而导致污染事件的加剧.研究结果有助于厘清城市大气NH_3的来源和转化机制及其对颗粒物的潜在贡献.     

pH值和离子对诺氟沙星在胡敏酸上吸附特征的影响

根据OECD Guideline 106批平衡实验,研究了pH值、Ca2+浓度和离子类型对诺氟沙星在胡敏酸上吸附特征的影响.结果表明,吸附系数(Kd)随着pH值的增大有先增加后减小的趋势,在pH 4.0和pH 6.0时吸附系数较大.红外光谱表明,pH 3.0有利于诺氟沙星和胡敏酸形成氢键; pH6.0和7.0时胡敏酸的羧基可能与诺氟沙星的氨基形成了肽键.诺氟沙星在胡敏酸上的吸附量和Kd值随着溶液中Ca2+离子浓度的增加而逐渐减小,表明两者之间存在阳离子吸附和竞争吸附.不同类型的阳离子和阴离子的加入都能导致诺氟沙星在胡敏酸的吸附特性存在差异.阳离子的影响趋势主要为价态的影响,即价态越高,在胡敏酸表面吸附位点的吸附能力就越强,对诺氟沙星吸附阻碍作用越显著,表现在诺氟沙星的最大吸附量(Qm)为:M+ (Na+、K+、NH4+) >M2+ (Mg2+、Ca2+、Zn2+);其次受阳离子的离子半径和水解作用的影响.而只有能水解的阴离子才能对诺氟沙星在胡敏酸上的吸附产生明显的阻碍作用.     

日本森林大气中过氧化物的浓度及其对森林植物的影响

为了研究森林衰退的原因,于2000,2001和2002年的8月,分别选择出现森林衰退的日本奥日光白根山落叶树森林和未出现森林衰退的长野县大芝高原红松森林设立监测点,对光化学氧化剂臭氧(O3)和过氧化物的浓度进行监测,同时利用人工气候室对森林植物山毛榉和白桦进行了50′10-9O3、100′10-9O3和50′10-9O3+2′10-9~3′10-9过氧化物(过氧化氢(H2O2)及甲基过氧化氢(MHP))的暴露实验.野外监测结果表明,监测期间奥日光和长野的O3平均浓度相同,奥日光的H2O2及MHP平均浓度均高于长野;大气中的H2O2和MHP总是与O3共存,并且其浓度随O3浓度的增加而增加.暴露实验结果表明,暴露于50′10-9O3+2′10-9~3′10-9过氧化物的山毛榉和白桦出现了不同于O3暴露的叶片伤害症状;与100′10-9O3相比,50′10-9O3+2′10-9~3′10-9过氧化物导致植物出现了严重的叶片伤害和显著的光合速率下降.研究结果表明,除O3外,大气中的过氧化物也是导致森林衰退的原因之一.     

Profile of Methane Concentrations in Soil and Atmosphere in Alpine Steppe Ecosystem on Tibetan Plateau

The methane concentration profile from -1.5m depth in soil to 32m height in air was measured in alpine steppe located in the permafrost area. Methane concentrations showed widely variations both in air and in soil during the study period. The mean concentrations in atmosphere were all higher than those in soil, and the highest methane concentration was found in air at the height of 16m with the lowest concentration occurring at the depth of 1.5m in soil. The variations of atmospheric methane concentrations did not show any clear pattern both temporally and spatially, although they exhibited a more steadystable state than those in soil. During the seasonal variations, the methane concentrations at different depths in soil were significantly correlated （R^2〉0.6） with each other comparing to the weak correlations （R^2〈0.2） between the atmospheric concentra- tions at different heights. Mean methane concentrations in soil significantly decreased with depth. This was the compositive influence of the decreasing production rates and the increasing methane oxidation rates, which was caused by the descent soil moisture with depth. Although the methane concentrations at all depths varied widely during the growing season, they showed very distinct temporal variations in the non-growing season. It was indicated from the literatures that methane oxidation rates were positively correlated with soil temperature. The higher methane concentrations in soil during the winter were determined by the lower methane oxidation rates with decreasing soil temperatures, whereas methane production rates had no reaction to the lower temperature. Relations between methane contribution and other environmental factors were not discussed in this paper for lacking of data, which impulse us to carry out further and more detailed studies in this unique area.     

水培芹菜净化不同浓度沼液的试验研究

沼液是畜禽粪尿经厌氧发酵产生的发酵液,随意排放将对环境产生一定危害,有效利用将带来一定的经济效益。用沼液水培芹菜,不仅可以为芹菜提供丰富的营养物质,还能达到废物资源化利用的目的。通过生物浮床工艺,将芹菜水培于不同浓度沼液中,研究其生长特性及其对污染物的去除能力,得出用沼液水培芹菜的最佳稀释倍数。结果表明:经过80 d的种植,稀释30倍的沼液水培的芹菜生物增长量最大;随着沼液稀释倍数的增加,芹菜的茎叶部分与根部中N的质量分数越小。芹菜对稀释100倍沼液中TN的去除率最高,为94.6%;对稀释10倍沼液中TP的去除率最高,为90.6%。沼液经稀释20~50倍之后水培芹菜的TN、TP去除率都较高;稀释30~40倍沼液水培芹菜所取得的环境效益和经济效益较高。     

酸性洗涤塔-生物滤塔-生物曝气池组合工艺处理恶臭气体NH3和H2S

采用酸性洗涤塔、生物滤塔和生物曝气池的组合工艺处理NH3、H2S恶臭混合气体,研究表明,该组合工艺对NH3和H2S有很好的去除效果,在进气流量为35 L/min,喷淋量45 L/h时,NH3进气浓度50.15~525.4 mg/m3,H2S进气浓度10.23~110.36 mg/m3时,NH3单一进气去除率稳定在99%以上,H2S单一进气去除率90%以上。混合进气后,NH3去除率几乎为100%,H2S的去除率提高至98%以上。在一定的浓度范围内,NH3和H2S之间的相互作用对两者的去除效果没有明显的影响,而且起到了相互促进降解的作用。同时,进气流量和填料层高度都会影响NH3、H2S的去除率。系统对进气容积负荷变化的缓冲能力强,在偶尔超负荷条件下运行并不能使系统崩溃,并且微生物对高负荷逐渐表现出适应性。大部分溶于水的氨由生物曝气池去除,去除率达到96.9%。