城市污泥堆肥对土壤温室气体排放的短期影响

采用田间试验,施用2种城市污泥堆肥（含生物质炭和不含生物质炭）,通过静态暗箱-气相色谱法研究污泥堆肥土地利用过程温室气体排放特征,探讨施用污泥堆肥的短期影响作用.结果表明,在观测时间内,N₂O排放主要集中在前3周,约占总排放量的87.9%~95.6%.N₂O排放量均随污泥堆肥施用量的增加而增加（P<0.05）,裸地N₂O排放量高于种植作物处理.施用含生物质炭污泥堆肥能减少土壤N₂O排放,且随着施用量的增加,N₂O减少量越大（P<0.05）.CH₄排放量较低,在试验前期和后期主要为负,总体表现为吸收CH₄.各处理吸收CH₄主要集中在第18d以后,其CH₄吸收量占总吸收量的52.1%~66.7%.施用含生物质炭污泥堆肥处理CH₄吸收量比不含生物质炭污泥堆肥处理低35.2%~62.2%,同时,裸地CH₄吸收量明显高于种植作物处理（P<0.05）.CO₂排放也主要集中在18d以后,约占排放总量的50.5%~61.8%.种植作物能促进CO₂的排放,种植作物处理是裸地的1.34~1.57倍.在观测时间内,污泥堆肥土地利用是CH₄的弱吸收汇,是N₂O和CO₂的排放源,施加污泥堆肥能显著增加土壤N₂O和CO₂的排放.施用生物质炭污泥堆肥短期内能够减少温室气体总排放量,温室气体减排量达到20.41%~62.51%.     

长江表层土壤多氯联苯污染特征及风险评价

采用气质联用仪（GC-MS）对长江流域13个干流断面及18个支流断面处沿岸表层土壤样品中的多氯联苯（PCBs）进行测定,分析其残留特征、污染来源和健康风险.结果表明,长江流域表层土中ΣPCBs的含量范围为：1.05~50.11ng/g dw,平均值为5.71ng/g dw,含量处于较低污染水平.干流的PCBs含量从上游到下游呈现逐渐增大的趋势,且PCBs在宜昌、岳阳、武汉、重庆等二三线城市总含量较高.PCB 17,PCB 18,PCB 44,PCB 74,PCB 87的检出率较高,三氯联苯、四氯联苯是主要的同系物,表明长江流域表层土壤主要以低氯联苯污染为主.主成分分析表明研究区域PCBs主要来自于1号国产变压器油、Aorclor 1242、1248、大气沉降及地表径流的混合污染源;对长江流域表层土壤健康风险评价表明,PCBs存在较小健康风险,呼吸摄入潜在风险低于经口摄入及皮肤接触.     

火山岩填料曝气生物滤池的SNAD工艺启动特性及功能菌丰度演替

为研究同步亚硝化、厌氧氨氧化耦合反硝化(SNAD)工艺在浸没式生物滤池反应器(SBAF)内的运行特性,同时接种亚硝化污泥和富集ANAMMOX的填料启动SNAD反应器.结果表明在60 mg·L~(-1)有机物浓度下,自养脱氮和反硝化实现较好的耦合,并在该浓度下稳定运行了67 d,其总氮去除率最高可达92.0%,COD去除率最高达82.9%,最高总氮去除负荷为2.3 kg·(m~3·d)~(-1).与全程自养脱氮(CANON)工艺相比,SNAD工艺的平均总氮去除率提高了12.6%.荧光定量PCR结果显示,系统启动后AOB菌的丰度有所增长,ANAMMOX菌的丰度增长了1个数量级,而NOB菌和反硝化菌的数量维持在较低水平(小于10~7 copies·g~(-1)),表明以火山岩为填料的浸没式生物滤池反应器有利于ANAMMOX和AOB的协同生长,可快速实现SAND工艺的启动.     

中国钢铁行业大气环境影响

本研究基于2015年在线监测等数据,分析中国钢铁行业主要工序(烧结和球团)排口烟气浓度情况,自下而上建立了2015年中国高时空分辨率钢铁行业大气污染物排放清单(HSEC, 2015),使用CAMx模型,定量模拟钢铁行业排放对区域大气污染物浓度贡献.结果表明, 2015年中国钢铁行业共排放SO_2、NO_x、PM_(10)、PM_(2.5)、PCDD/Fs、VOCs、CO、BC、OC、EC和F分别为37.48万t、 72.05万t、 33.48万t、 15.03万t、 1.91 kg、 84.29万t、 3 478.85万t、 0.64万t、 0.83万t、 0.08万t和0.77万t.从区域角度:上海和天津钢铁行业单位面积污染排放强度最大,对区域大气污染贡献比例较高.从工序角度:2015年烧结和球团烟气排口月平均浓度降低.从污染物角度:2015年钢铁行业排放NO_x对区域污染物浓度贡献最大,NO_x具有较大的减排潜力.     

Characterization of submicron particles during autumn in Beijing, China

In this study, we performed a highly time-resolved chemical characterization of nonrefractory submicron particles(NR-PM_1) in Beijing by using an Aerodyne high-resolution time-of-flight aerosol mass spectrometer(HR-ToF-AMS). The results showed the average NR-PM_1 mass concentration to be 56.4 ± 58.0 μg/m~3, with a peak at 307.4 μg/m~3. Due to the high frequency of biomass burning in autumn, submicron particles significantly increased in organic content, which accounted for 51% of NR-PM_1 on average. Secondary inorganic aerosols(sulfate + nitrate + ammonium) accounted for 46% of NR-PM_1, of which sulfate,nitrate, and ammonium contributed 15%, 20%, and 11%, respectively. To determine the intrinsic relationships between the organic and inorganic species, we used the positive matrix factorization(PMF) model to merge the high-resolution mass spectra of the organic species and NO+and NO_2~+ions. The PMF analysis separated the mixed organic and nitrate(NO+and NO_2~+) spectra into four organic factors, including hydrocarbon-like organic aerosol(HOA), oxygenated organic aerosol(OOA), cooking organic aerosol(COA), and biomass burning organic aerosol(BBOA), as well as one nitrate inorganic aerosol(NIA) factor. COA(33%) and OOA(30%) contributed the most to the total organic aerosol(OA) mass, followed by BBOA(20%) and HOA(17%). We successfully quantified the mass concentrations of the organic and inorganic nitrates by the NO+and NO2+ions signal in the organic and NIA factors. The organic nitrate mass varied from 0.01-6.8 μg/m~3, with an average of 1.0 ±1.1 μg/m~3, and organic nitrate components accounted for 10% of the total nitrate mass in this observation.     

β-环糊精/环氧氯丙烷聚合物的制备及其对双酚S的吸附特性

BPS（双酚S）用途广泛,但存在水环境污染问题,容易引起类似于双酚A的雌激素反应,因此需要寻求高效的吸附剂从水溶液中将其脱除.在NaOH水溶液中,以环氧氯丙烷为交联剂,合成了β-CDP（β-环糊精/环氧氯丙烷聚合物）,用于吸附水溶液中的BPS.基于此,考察了吸附时间、pH、初始ρ（BPS）、β-CDP用量对吸附性能的影响以及β-CDP的再生性能,探讨了吸附动力学、等温吸附模型和吸附机理.结果表明:①在温度为298 K、pH为5.4、β-CDP用量为0.05 g、初始ρ（BPS）为100 mg/L、BPS溶液体积为50 mL、吸附时间为60 min的条件下,BPS吸附量为69.7 mg/g,吸附率为69.7%;②吸附动力学符合准二级动力学模型,表明化学吸附为速率控制步骤;③Langmuir吸附等温模型的成功拟合表明,吸附BPS在β-CDP表面上形成了单分子层覆盖;④β-CDP吸附BPS为放热过程,低温有利于吸附的进行;⑤与初始吸附量（69.7 mg/g）相比,β-CDP连续再生6次,BPS吸附量仍可达68.1 mg/g;⑥吸附机理是通过BPS的羟基与β-CDP形成氢键作为推动力,并借助β-CD（β-环糊精）空腔内部的疏水作用,使得BPS进入空腔形成包结物.研究显示,β-CDP对水溶液中的BPS具有良好的吸附性能,再生循环使用稳定性高,具有较高的性价比.      

紫外诱变选育高原环境絮凝菌及其絮凝条件优化

为获得耐低温且絮凝优异的絮凝菌,对一株分离得到的絮凝菌进行紫外诱变和5℃低温胁迫培养,并对诱变优势菌进行应用条件优化.结果表明:①原始菌为蜡状芽孢杆菌（Bacillus cereus）.②紫外诱变和低温胁迫培养得到的目标诱变菌FB-5对生活污水絮凝率达75.35%,具有良好的遗传稳定性.③单因素试验确定最佳絮凝条件,即絮凝菌投加量为0.90 mL/（50 mL）、pH为7.4、助凝剂加量为1.0 mL/（50 mL）、处理时间为15 min;筛选出影响诱变菌絮凝能力最显著的3个因素为絮凝菌投加量、pH和助凝剂加量;通过Box-Behnken响应面试验得到最佳净化的应用条件,即絮凝菌投加量为0.90 mL/（50 mL）、pH为7.38、助凝剂加量为1.04 mL/（50 mL）.④验证试验确定絮凝率达97.01%,BOD₅、COD_Cr、浊度和色度去除率均达到97%以上,出水水质满足GB 18918—2002《城镇污水处理厂污染物排放标准》一级A标准.研究显示,紫外诱变联合低温胁迫技术以及单因素与响应面结合优化絮凝条件可以大幅度提高原始菌株的絮凝能力,低温诱变菌FM-5能使高寒地区城市生活污水中悬浮固体大幅降低,同时去除水体中多种污染物.      

Investigating missing sources of glyoxal over China using a regional air quality model (RAMS-CMAQ)

Currently, modeling studies tend to significantly underestimate observed space-based glyoxal(CHOCHO) vertical column densities(VCDs), implying the existence of missing sources of glyoxal. Several recent studies suggest that the emissions of aromatic compounds and molar yields of glyoxal in the chemical mechanisms may both be underestimated, which can affect the simulated glyoxal concentrations. In this study, the influences of these two factors on glyoxal amounts over China were investigated using the RAMS-CMAQ modeling system for January and July 2014. Four sensitivity simulations were performed, and the results were compared to satellite observations. These results demonstrated significant impacts on glyoxal concentrations from these two factors.In case 1, where the emissions of aromatic compounds were increased three-fold,improvements to glyoxal VCDs were seen in high anthropogenic emissions regions. In case 2, where molar yields of glyoxal from isoprene were increased five-fold, the resulted concentrations in July were 3–5-fold higher, achieving closer agreement between the modeled and measured glyoxal VCDs. The combined changes from both cases 1 and 2 were applied in case 3, and the model succeeded in further reducing the underestimations of glyoxal VCDs. However, the results over most of the regions with pronounced anthropogenic emissions were still underestimated. So the molar yields of glyoxal from anthropogenic precursors were considered in case 4. With these additional mole yield changes(a two-fold increase), the improved concentrations agreed better with the measurements in regions of the lower reaches of the Yangtze River and Yellow River in January but not in July.     

Insights into the formation of secondary organic carbon in the summertime in urban Shanghai

To investigate formation mechanisms of secondary organic carbon(SOC) in Eastern China,measurements were conducted in an urban site in Shanghai in the summer of 2015. A period of high O_3 concentrations(daily peak 120 ppb) was observed, during which daily maximum SOC concentrations exceeding 9.0 μg/(C·m~3). Diurnal variations of SOC concentration and SOC/organic carbon(OC) ratio exhibited both daytime and nighttime peaks. The SOC concentrations correlated well with O_x(= O_3+ NO_2) and relative humidity in the daytime and nighttime, respectively, suggesting that secondary organic aerosol formation in Shanghai is driven by both photochemical production and aqueous phase reactions. Single particle mass spectrometry was used to examine the formation pathways of SOC. Along with the daytime increase of SOC, the number fraction of elemental carbon(EC) particles coated with OC quickly increased from 38.1% to 61.9% in the size range of 250–2000 nm, which was likely due to gas-to-particle partitioning of photochemically generated semi-volatile organic compounds onto EC particles. In the nighttime, particles rich in OC components were highly hygroscopic, and number fraction of these particles correlated well with relative humidity and SOC/OC nocturnal peaks. Meanwhile, as an aqueous-phase SOC tracer, particles that contained oxalate-Fe(III) complex also peaked at night. These observations suggested that aqueous-phase processes had an important contribution to the SOC nighttime formation. The influence of aerosol acidity on SOC formation was studied by both bulk and single particle level measurements, suggesting that the aqueous-phase formation of SOC was enhanced by particle acidity.     

Alkali resistance promotion of Ce-doped vanadium-titanic-based NH3-SCR catalysts

The effect of K deactivation on V_2O_5/WO_3-TiO_2 and Ce-doped V_2O_5/WO_3-TiO_2 catalysts in the selective catalytic reduction(SCR) of NOxby NH_3 was studied.Ce-doped V_2O_5/WO_3-TiO_2 showed significantly higher resistance to K deactivation than V_2O_5/WO_3-TiO_2.Ce-doped V_2O_5/WO_3-TiO_2 with K/V = 4(molar ratio) showed 90% NOxconversion at 350°C,whereas in this case V_2O_5/WO_3-TiO_2 showed no activity.The fresh and K-poisoned V_2O_5/WO_3-TiO_2 and Ce-doped V_2O_5/WO_3-TiO_2 catalysts were investigated by means of in situ diffuse reflectance infrared Fourier transform spectroscopy(DRIFTS),NH_3-temperature progress decomposition(NH_3-TPD),X-ray photoelectron spectroscopy(XPS) and H2-temperature program reduction(H_2-TPR).The effect of Ce doping on the improving resistance to K of V_2O_5/WO_3-TiO_2 were discussed.