冬季猪粪固体堆放过程中NH3、N2O和NO排放特征研究

针对农村猪粪典型处理方式中的固体堆放管理,研究猪粪在冬季(2012年11月~2013年2月)固体堆放过程中NH3、N2O和NO排放特征.实验共设两个处理——无覆盖(non-covered,NC)和水稻秸秆覆盖(covered,C),堆放时间为73 d,期间进行了3次翻堆操作.实验观测了3种含氮气体(NH3、N2O和NO)的排放通量和堆体剖面N2O浓度变化.结果表明,猪粪固体堆放过程中NH3、N2O和NO排放累积量(以N计)分别占初始TN的比例为2.1%~2.6%、0.02%和~0.000 25%.两个处理的含氮气体排放通量变化趋势基本一致,且有覆盖堆体的含氮气体的排放量略低于无覆盖堆体.在堆放初期,NH3排放量最先出现峰值,之后N2O和NO排放开始增加.NH3和NO在固体堆放的中前期呈现互为消长的变化趋势;到堆放后期,N2O开始出现比前期高出两倍的排放高峰,而NH3和NO出现小幅增长.翻堆前后,NH3的排放无明显变化,而N2O排放在翻堆后均出现降低的变化,NO排放却出现升高的变化.     

废茶活性炭脱硫脱硝性能的应用研究

为探讨废茶活性炭对于SO2和NO脱除作用的制约因素,分别考察了材料孔径结构、石墨化程度及表面结构对其脱硫脱硝性能的影响,同时研究了其吸附机制及动力学过程.结果表明,较高的石墨化程度是影响材料脱硫性能的主要因素,微孔径较小且含氮碱性基团较高时有利于SO2的脱除;发达的中孔结构是制约NO脱除效率的关键因素,含氮碱性基团对NO的脱除具有一定的促进作用;烟气中SO2和NO共存时,材料的脱硫脱硝性能均有所降低,氧气和水蒸气的加入能够改善其脱硫脱硝效率;废茶活性炭在无水环境下对于SO2和NO的吸附作用均以物理吸附为主,水蒸气的存在促进了材料对SO2的化学吸附;通过动力学模型的拟合发现,Bangham吸附模型能够很好地描述材料脱硫脱硝的动力学过程,其R2均高于0.989,材料对于SO2和NO的吸附速率常数均随氧气和水蒸气的加入而减小.     

碳底物含量对厌氧条件下水稻土N2、N2O、NO、CO2和CH4排放的影响

理解底物碳氮对厌氧条件下水稻土排放氮素气体——氮气(N2)、氧化亚氮(N2O)和一氧化氮(NO)以及二氧化碳(CO2)和甲烷(CH4)的影响,有助于制定合理的温室气体减排措施,定量了解反硝化产物组成对碳底物水平的依赖性,也有助于氮转化过程模型研发中制定正确的关键过程参数选取方法或参数化方案.本研究采用粉砂壤质水稻土为研究对象,设置对照(CK)和加碳(C+)两个处理,前者的初始硝态氮和可溶性有机碳(DOC)含量分别为~50 mg·kg-1和~28 mg·kg-1,后者的分别为~50 mg·kg-1和~300 mg·kg-1.采用氦环境培养-气体及碳氮底物直接同步测定系统,研究了完全厌氧条件下碳底物水平对上述气体排放的影响.结果表明,CK处理无CH4排放,而C+处理可观测到CH4排放;C+处理的综合增温潜势显著高于CK处理(P<0.01);NO、N2O和N2排放量占这3种氮素气体排放总量的比重,在CK处理分别约为9%、35%和56%,在C+处理分别约为31%、50%和19%,处理间差异显著(P<0.01).由此表明,碳底物水平可显著改变所排放氮素气体的组成;对于旱地阶段硝态氮比较丰富的水稻土,避免在淹水前或淹水期间施用有机肥,有利于削减温室气体排放.     

北京市海淀区NO_2污染特征及气象要素关系分析研究

利用2006年-2009年北京市环境保护局海淀区香山站、万柳站和北部新区站的NO2资料和相对应的气象资料,对NO2的污染特征进行分析发现:NO2浓度达到三级的日数平均为5 d,呈逐年减少的趋势。NO2超标日分布在1-4月和10-12月,浓度峰值在上午10:00和19:00-23:00,谷值在上午7:00时,且节假日NO2浓度略高于工作日。通过相关分析,NO2的浓度随温度、风速、气压、降水量的增高而降低,随相对湿度的升高而升高,且偏南风易造成污染。     

大气环境影响评价中存在的主要问题及注意事项

虽然《环境影响评价技术导则-大气环境》(HJ 2.2-2008)规定了各等级评价的现状监测内容和要求,但在具体的大气环境现状监测实践中,还存在不少技术性的问题亟需解决。本文结合工作实际,阐述了大气环境影响评价现状监测中存在的主要问题,并提出了意见和建议,希望能为环境监测人员做好大气环境影响评现状监测工作提供有益的借鉴。     

港口NO_2、PM_(10)与天气因素的多重分形研究

对港口大气污染物NO_2、PM_(10)和天气因素进行MF-DCCA分析研究,系统地分析了NO_2、PM_(10)与3种天气因素之间复杂关系。从整体角度上,研究表明NO_2、PM_(10)与天气因素均具有长程相关性、多重分形特性;天气因素对PM_(10)的影响程度要强于对NO_2的影响程度。从四季的角度上,研究发现,NO_2、PM_(10)浓度在春季有下降趋势,在秋季有上扬趋势。     

焙烧温度对Fe2O3/SAPO-34催化剂低温NH3选择性催化还原NO性能的影响

采用尿素沉淀法制备了一系列Fe_2O_3/SAPO-34催化剂,考察了催化剂焙烧温度(200、300、400、500℃)对低温NH_3选择性催化还原(NH_3-SCR)NO性能的影响,并利用X射线衍射(XRD)、N_2吸附-脱附、原子吸收光谱(AAS)、场发射扫描电镜(FE-SEM)、X射线光电子能谱(XPS)、H_2程序升温还原(H_2-TPR)、NH_3程序升温脱附(NH_3-TPD)等多种手段对催化剂的表面结构和物理化学性质进行表征分析.XRD和FE-SEM分析表明,在较低的焙烧温度(400℃)下,铁物种能够高度均匀地负载在SAPO-34表面上.NH_3-TPD和H_2-TPR分析表明,高分散状态的Fe_2O_3使催化剂暴露出更多的强酸位和活性位,有利于提高催化剂的NH_3吸附和活化能力及氧化还原性能,从而使催化剂呈现出更高的低温SCR活性.BET和XPS分析表明,在较低的焙烧温度下,Fe_2O_3/SAPO-34催化剂具有更大的比表面积和更高的化学吸附氧比例,促进NO氧化为中间产物NO_2,从而加快低温SCR反应的进行.活性测试结果表明,300℃焙烧的Fe_2O_3/SAPO-34催化剂具有最佳的低温活性和较强的抗硫抗水性能,在空速为40000 h~(-1)的条件下,且反应温度为190~240℃时,NO转化率达90%以上且N_2选择性接近100%.     

尖晶石型MnCo_2O_4催化剂的制备及SCR性能研究

用柠檬酸配位燃烧法制备了尖晶石复合金属氧化物MnCo2O4,使用X射线衍射仪、傅立叶红外分析仪对其进行了表征,并进一步在固定床反应器中考查了该催化剂的催化氧化、还原NO的性能以及SO2的影响。结果表明,所制备的MnCo2O4催化剂呈现典型的尖晶石结构,在300℃,空速20000h-1时,NO氧化率可以达到30%,而NH3催化还原NO的效率可达99.5%,但SO2对其还原性能有明显影响。     

Effects of support acidity on the reaction mechanisms of selective catalytic reduction of NO by CH4 in excess oxygen

The reaction mechanisms of selective catalytic reduction (SCR) of nitric oxide (NO) by methane (CH₄) over solid superacid-based catalysts were proposed and testified by DRIFTS studies on transient reaction as well as by kinetic models. Catalysts derived from different supports would lead to different reaction pathways, and the acidity of solid superacid played an important role in determining the reaction mechanisms and the catalytic activities. Higher ratios of Br?nsted acid sites to Lewis acid sites would lead to stronger oxidation of methane and then could facilitate the step of methane activation. Strong Br?nsted acid sites would not necessarily lead to better catalytic performance, however, since the active surface NO_y species and the corresponding reaction routes were determined by the overall acidity strength of the support. The reaction routes where NO₂ moiety was engaged as an important intermediate involved moderate oxidation of methane, the rate of which could determine the overall activity. The reaction involving NO moiety was likely to be determined by the step of reduction of NO. Therefore, to enhance the SCR activity of solid superacid catalysts, reactions between appropriate couples of active NO_y species and activated hydrocarbon intermediates should be realized by modification of the support acidity.     

A comparative investigation of NdSrCu1-xCoxO4-σ and Sm1:8Ce0:2Cu1-xCoxO4-σ(x: 0-0.4) for NO decomposition

A series of single-phase T-structured NdSrCu1??xCoxO4?? with oxygen vacancies and T0-structured Sm1:8Ce0:2Cu1??xCoxO4?? (x: 0–0.4) with oxygen excess were prepared using ultrasound-assisted citric acid complexing method, and characterized by means of techniques such as thermogravimetric analysis and NO temperature-programmed desorption (NO-TPD). The catalytic activities of these materials were evaluated for the decomposition of NO. It was found that the NdSrCu1??xCoxO4?? catalysts were of oxygen vacancies whereas the Sm1:8Ce0:2Cu1??xCoxO4?? ones possessed excessive oxygen (i.e., over-stoichiometric oxygen); with a rise in Co doping level, the oxygen vacancy density of NdSrCu1??xCoxO4?? decreased while the over-stoichiometric oxygen amount of Sm1:8Ce0:2Cu1??xCoxO4?? increased. The NO-TPD results revealed that NO could be activated much easier over the oxygen-deficient perovskite-like oxides than over the oxygen-excessive perovskite-like oxides, with the NdSrCuO3:702 catalyst showing the best e ciency in activating NO molecules. Under the conditions of 1.0% NO/helium, 2800 hr??1, and 600–900°C, the catalytic activity of NO decomposition followed the order of NdSrCuO3:702 > NdSrCu0:8Co0:2O3:736 > NdSrCu0:6Co0:4O3:789 > Sm1:8Ce0:2Cu0:6Co0:4O4:187 > Sm1:8Ce0:2Cu0:8Co0:2O4:104 > Sm1:8Ce0:2CuO4:045, in concord with the sequence of decreasing oxygen vacancy or oxygen excess density. Based on the results, we concluded that the higher oxygen vacancy density and the stronger Cu3+/Cu2+ redox ability of NdSrCu1??xCoxO4?? account for the easier activation of NO and consequently improve the catalytic activity of NO decomposition over the catalysts.