多层填料生物转鼓去除NO废气的效能比较研究

生物转鼓过滤器能有效去除一氧化氮(NO)废气,为进一步提高生物转鼓过滤器的去除效能,实验改变了生物转鼓的填料结构,并与单层填料的生物转鼓进行了比较研究.结果表明,多层填料生物转鼓比单层填料生物转鼓更能有效去除NO,运行也更加稳定.8个月的连续运行实验表明,多层填料生物转鼓对NO去除率稳定在53.9％ ～93.4％之间,平均去除效率79.8％,而单层填料生物转鼓的平均去除率仅有68.7％;在相同实验条件下,空床停留时间(EBRT)可从单层填料生物转鼓的86.4 s降至多层填料生物转鼓的57.6 s.多层填料生物转鼓的最优工艺条件为,营养液量为1.3～3L,转速为0.75 r·min-1,在以葡萄糖为碳源时,TOC＞ 1250 mg·L-1后,去除效率增长幅度趋于平缓.     

生物陶粒反应器的氢自养反硝化研究

利用氢自养反硝化生物陶粒反应器处理硝酸盐废水,探讨了生物陶粒反应器中氢自养反硝化生物脱氮的实现过程.考察了水力停留时间、进水硝氮负荷、进水pH值、温度、供氢量等因素对反应器脱氮效果的影响.结果表明,当水力停留时间为24 h和48 h时,反应器对硝酸氮的平均去除率分别达到94.54%和97.47%.在水力停留时间为5~16 h时,NO-3-N去除率随水力停留时间的缩短而降低;进水NO-3-N浓度较低时,NO-3-N的降解速率随其浓度的升高而增大,当NO-3-N浓度大于110mg·L-1时,氢自养反硝化反应受到抑制;中偏碱性环境较酸性或碱性环境更利于反应器对硝酸盐的去除;反应器有较宽的温度适应范围,最适温度为25~30℃;当反应器供氢不足时,脱氮效果明显降低,表明了氢自养反硝化菌对氢气利用的专一性.在整个运行阶段,出水中亚硝酸氮浓度一直保持在较低水平.     

黄河下游滩区开封段土壤重金属分布特征及其潜在风险评价

按照土壤采样规范,对开封段黄河滩区及滩外土壤采样,表层0～20 cm样品48个,垂直剖面采样100 cm,2个;并按照土壤化学分析方法,对Pb、Cr、Hg、As和Cd这5种重金属进行分析;最后,按照国家土壤一级标准,采用单因子污染指数、内梅罗综合污染指数和Hkanson潜在生态危害指数法对开封市黄河滩区土壤重金属分布特征、污染状况和潜在生态危害进行了分析.结果表明:①开封市黄河滩区土壤Pb、Cr、Hg、As和Cd这5种重金属含量就平均值而言,Cr的平均含量最大,Pb、Hg的平均含量最小.除Hg之外,其它重金属元素的变异系数均较小,说明重金属Hg存在较大差异;滩区土壤的主要污染元素为Hg、As、Pb,其中Pb的污染为普遍性污染.Cr和Cd在各村间变化不大,且含量均在国家一级标准(自然保护区)以下.②土壤各重金属元素的空间分布特征研究区内上下段之间分异明显,上段呈清洁状态,中段有少量污染,下段表现出明显富集的分布状态;③以黄河大堤为界,滩区内外重金属分异与居民点分布密切相关,在滩区上段(西南部)居民集中,土壤各重金属浓度较高,表现为沿河区<大堤外,中下游段(滩区东北部)重金属含量大于大堤外土地,下游段东北趋向于污染富集.④以重金属平均单项潜在生态风险指数(Eri)评价表明,开封市黄河滩区土壤Hg的潜在生态风险达到强烈水平,Pb在重金属综合潜在生态风险的贡献率高达50.5%,是最主要的生态风险重金属,各个重金属的污染程度为Hg>Pb>As>Cd>Cr.⑤各重金属生态危害的次序为Hg>Cd>As>Pb>Cr.由RI值对应的潜在生态风险等级可知,开封市黄河滩区土壤存在中等级别重金属潜在生态危害.     

20 a来中国占补耕地光温生产潜力时空特征

研究占补耕地光温生产潜力的时空特征对指导耕地资源开发与粮食生产具有重要意义。论文基于1980年代末-2010年的多期土地利用和多年平均光温生产潜力,以占用耕地与增补耕地单位面积光温生产潜力为依据,分析20 a来中国占补耕地光温生产潜力时空特征,并进一步探讨其对光温生产潜力总量的影响。结果表明:①1980年代末-2010年,全国耕地存在明显的占优补劣情况;②从各分区看,东北平原主产区、北方干旱半干旱主产区、青藏高原区、华南主产区、云贵高原区占用耕地单位面积光温生产潜力持续高于增补耕地,长江中下游主产区占用耕地单位面积光温生产潜力持续低于增补耕地,四川盆地及周边地区、黄土高原区、海南由占优补劣变为占劣补优,黄淮海平原区由占劣补优变为占优补劣;③占优补劣对全国光温生产潜力总量变化有显著影响;④东北平原主产区等我国耕地开垦的主要区域受占优补劣的影响较大,华南主产区等耕地损失区受占优补劣的影响相对较小,占劣补优对缩小耕地占用对光温生产潜力总量影响的作用并不大。     

Effect of ammonium on nitrous oxide emission during denitrification with different electron donors

Nitrous oxide(N2O) emission during denitrification is receiving intensive attention due to its high potential to cause greenhouse effects.In this study,denitrifiers were acclimated in sequencing batch reactors with methanol or acetate as the electron donor and nitrate as the electron acceptor.The effects of ammonium on N2O emission were examined in batch experiments with various electron donors.With the addition of ammonium,N2O emission increased under all the examined conditions compared to experiments without ammonium addition.With different electron donors,the highest ratio of N2O emission to the removed oxidized nitrogen was 0.70% for methanol,5.34% for acetate,and 34.79% for polyhydroxybutyrate.     

Identification of key factors governing chemistry in groundwater near the water course recharged by reclaimed water at Miyun County, Northern China

Reclaimed water was successfully used to recover the dry Chaobai River in Northern China, but groundwater may be polluted. To ensure groundwater protection, it is therefore critical to identify the governing factors of groundwater chemistry. Samples of reclaimed water, river and groundwater were collected monthly at Chaobai River from January to September in 2010. Fifteen water parameters were analyzed. Two kinds of reclaimed water were different in type (Na-Ca-Mg-Cl-HCO3 or Na-Ca-Cl-HCO3 ) and concentration of nitrogen. The ionic concentration and type in river were similar to reclaimed water. Some shallow wells near the river bed had the same type (Na-Ca-Mg-Cl-HCO3 ) and high concentration as reclaimed water, but others were consistent with the deep wells (Ca-Mg-HCO3 ). Using cluster analysis, the 9 months were divided into two periods (dry and wet seasons), and all samples were grouped into several spatial clusters, indicating different controlling mechanisms. Principal component analysis and conventional ionic plots showed that calcium, magnesium and bicarbonate were controlled by water-rock interaction in all deep and some shallow wells. This included the dissolution of calcite and carbonate weathering. Sodium, potassium, chloride and sulfate in river and some shallow wells recharged by river were governed by evaporation crystallization and mixing of reclaimed water. But groundwater chemistry was not controlled by precipitation. During the infiltration of reclaimed water, cation exchange took place between (sodium, potassium) and (calcium, magnesium). Nitrification and denitrification both happened in most shallow groundwater, but only denitrification in deep groundwater.     

Adsorption of Cr(Ⅲ) from acidic solutions by crop straw derived biochars

Cr（Ⅲ） adsorption by biochars generated from peanut, soybean, canola and rice straws is investigated with batch methods. Adsorption of Cr（Ⅲ） increased as pH rose from 2.5 to 5.0. Adsorption of Cr（Ⅲ） led to peak position shifts in the FFIR-PAS spectra of the biochars and made zeta potential values less negative, suggesting the formation of surface complexes between Cr^3＋ and functional groups on the biochars. The adsorption capacity of Cr（Ⅲ） followed the order： peanut straw char 〉 soybean straw char 〉 canola straw char 〉 rice straw char, which was consistent with the content of acidic functional groups on the biochars. The increase in Cr^3＋ hydrolysis as the pH rose was one of the main reasons for the increased adsorption of Cr（Ⅲ） by the biochars at higher pH values. Cr（llI） can be adsorbed by the biochars through electrostatic attraction between negative surfaces and Cr^3＋, but the relative contribution of electrostatic adsorption was less than 5%. Therefore, Cr（Ⅲ） was mainly adsorbed by the biochars through specific adsorption. The Langumir and Freundlich equations fitted the adsorption isotherms well and can therefore be used to describe the adsorption behavior of Cr（Ⅲ） by the crop straw biochars. The crop straw biochars have great adsorption capacities for Cr（Ⅲ） under acidic conditions and can be used as adsorbents to remove Cr（Ⅲ） from acidic wastewaters.     

反硝化菌株DA-1的脱氮研究

菌株DA-1被发现能在好氧和厌氧环境中将硝酸盐转化为气态氮。在以NO3-为唯一氮源的条件下研究了碳源、C/N和pH值对菌株DA-1好氧和厌氧反硝化脱氮的影响。结果表明:同等条件下,48 h内菌株DA-1的厌氧脱氮效率高于好氧脱氮率;菌株DA-1能在好氧和厌氧条件下利用乙酸、柠檬酸以及葡萄糖进行细胞增殖和反硝化。在厌氧条件下,三者作为碳源时的反硝化效率分别为(34.04±0.15)%、(22.72±0.32)%和(11.32±0.06)%,均低于好氧条件下的(25.38±0.14)%、(17.52±0.11)%和(8.06±0.01)%。2种条件下均是乙酸为碳源时反硝化效率最高。而丁二酸仅能在厌氧环境中作为电子供体参与反硝化反应。C/N越高越有利于菌株DA-1的厌氧反硝化,当C/N为10时,反硝化效率最高为(35.06±0.19)%。而在好氧条件下,菌株反硝化效率随着C/N的升高,先升高再降低,当C/N为8时,反硝化效率最高;好氧和厌氧脱氮的最适pH值为7.0。体系偏酸或者偏碱都会造成菌株DA-1脱氮效率的降低并出现亚硝酸盐累积。厌氧环境中pH=5.0时累积的亚硝酸盐浓度高达(8.95±2.05)mg/mL。     

2种生物反硝化法去除地下水中硝酸盐的研究

采用砂柱装置,在实验室研究了自养微生物和异养微生物2种生物反硝化方法对地下水中硝酸盐的去除效果。自养反硝化反应在以硫作为电子供体的硫/石灰石/细沙反应柱中进行,异养反硝化反应在石灰石/细沙反应柱中进行,进水增加乙醇作为外加碳源。实验结果用以比较2种反硝化方法在硝酸盐去除率、微生物反应动力学和反应产物三者的异同。结果表明,自养反硝化反应中NO3--N去除率达95.4%,异养反硝化反应去除率可达99.3%;分别与Monod微生物0级、1/2级和1级反应动力学方程进行拟合,2种反硝化反应均符合1/2级微生物反应动力学,适合用1/2级微生物反应方程描述;在反应结束阶段,自养反硝化主要反应产物SO42-出水浓度低于250mg/L,异养反硝化副产物CH3OO-易成为二次污染源,异养反硝化的反硝化速率明显高于自养反硝化反应。     

基于DEA的上海市非中心城区工业生态效率研究

运用数据包络分析（DataEnvelopmentanalysis,DEA）的方法,从环境污染和资源消耗两个方面,建立了工业生态效率评价的指标体系,评价了2008年上海市非中心城区各区县的工业生态效率。结果表明,松江区处于上海市工业生态效率的前沿面,9个区县中有2／3区县的工业生态效率优于上海市平均水平。其中,崇明、嘉定和青浦处于规模报酬递增阶段,奉贤、闵行、浦东、金山、宝山则处于规模报酬递减阶段。最后,基于C2R模型对各区县的投入产出情况进行了优化调整,认为削减SO2的排放量和减少能源的消耗应是各区县提高工业生态效率的关键。