地下水水化学组成对Fe(Ⅱ)氧化过程中锰氧化菌失活的影响

溶解态Fe(Ⅱ)和Mn(Ⅱ)常共存于还原性地下水中,受O2扰动Fe(Ⅲ)会快速发生氧化.为了解地下水化学组成对Fe(Ⅱ)氧化过程中锰氧化菌Pseudomonas putida MnB1失活的影响,利用平板计数和邻菲咯啉显色法研究了 pH值、天然有机质和阴阳离子对Fe(Ⅱ)氧化过程中MnB1菌株活菌数量和Fe(Ⅱ)浓度变...     

丹江口水库浮游细菌和氮磷循环基因垂直分布特征及其驱动因素

丹江口水库作为南水北调中线工程水源地,不同深度浮游细菌群落组成、 氮磷循环功能及其驱动因素尚未清晰. 选取丹江口水库5个生态点位,采用宏基因组学研究表层、 中层和底层垂直分布浮游细菌群落组成,分析预测氮磷循环功能及其驱动因素. 结果表明,丹江口水库主要由变形菌门、 放线菌门和浮霉菌门等优势种群组成,不同深度来源的浮游细菌群落结构具有显著差异,水温（T）、 氧化还原电位（ORP）、 溶解氧（DO）和Chla是影响浮游细菌群落组成的主要因素. 氮循环功能基因分析表明,主要涉及生物固氮过程、 硝化作用、 反硝化作用和异化硝酸盐还原作用等7个主要途径的gltB、 glnA、 gltD、 gdhA和NRT等39个氮循环功能基因. 磷循环功能基因分析表明,主要涉及有机磷矿化、 无机磷溶解、 调节等6个主要途径的pstS、 ppx-gppA、 glpQ和ppk1等54个磷循环功能基因. 聚类分析表明不同深度是影响氮磷循环功能基因组成和丰度的主要因素,表层和底层氮磷循环功能基因丰度高于中层样品. 奇异球菌属、 嗜氢菌属、 Limnohabitans和棍状杆菌属等是氮磷循环的关键物种. DO、 pH、 T、 总溶解性固体（TDS）、 电导率（EC）和Chla与氮磷循环功能基因显著相关,以上环境因子随丹江口水库深度增加浓度降低或升高,导致浮游细菌氮磷循环功能基因呈明显的垂直分布特征. 通过揭示丹江口水库不同深度浮游细菌群落组成、 氮磷循环功能及其影响因素,可为丹江口浮游细菌生态功能和多样性保护发挥潜在的作用.     

大气CO2浓度增高对不同供氮水平下水稻生长和化感物质释放的影响

利用开放式空气CO2浓度升高(free air carbon-dioxide enrichment,FACE)平台中的水培试验,研究了低氮(LN:10 mg·L-1)和高氮(HN:30 mg·L-1)水平下,大气CO2浓度升高对化感与非化感水稻(Oryza sativa L.)品种的生长、碳氮比(C/N)和化感物质含量的影响,并分析了CO2浓度升高条件下水稻C/N和化感物质含量间的相互关系.结果表明:CO2浓度升高对化感(PI)与非化感水稻品种(秀水)的生长均有极显著促进作用.CO2浓度升高后,LN条件下水稻C/N显著增加,HN条件下则无显著变化.CO2浓度升高后化感水稻品种次生代谢物质含量增加,特征化感物质含量增加,非化感品种的这种变化不显著.化感水稻品种C/N分别与次生代谢物质含量和特征化感物质含量之间呈显著正相关关系.     

压裂返排液循环利用技术的应用

开发了压裂返排液"水质调节—混凝沉淀—精细过滤"处理工艺.将返排液pH调为7.8～8.0,采用无机铝盐混凝剂+有机阳离子高分子絮凝剂+沉淀剂(FJ-3)处理,采用20μm有机滤膜对混凝沉淀后水进行过滤处理,再经季铵盐类杀菌剂处理,出水再用于配制胍胶压裂液.无论是基液基础性能还是胶液耐温耐剪切能力以及破胶性能都与自来水配...     

赤霉素浓度对色木槭(Acer mono Maxim.)种子萌发的影响

岷江上游彩叶林生态系统是我国西南地区特有的关键生态系统类型,具有水源涵养、水土保持和气候调节等重要的生态功能,而且具有显著的景观美学价值,是区域特色生态旅游经济的重要基础.由于受到自然灾害破坏和水电站的修建等人为干扰,目前岷江上游彩叶林系统毁坏严重且残存量不多,亟待恢复和重建.色木槭(Acer mono Maxim.)...     

Nitrogen cycling of atmosphere-plant-soil system in the typical Calamagrostis angustifolia wetland in the Sanjiang Plain, Northeast China

The nitrogen (N) distribution and cycling of atmosphere-plant-soil system in the typical meadow Calamagrostis angustifolia wetland (TMCW) and marsh meadow Calamagrostis angustifolia wetland (MMCW) in the Sanjiang plain were studied by a compartment model. The results showed that the N wet deposition amount was 0.757 gN/(m2·a), and total inorganic N (TIN) was the main body (0.640 gN/(m2·a)). The ammonia volatilization amounts of TMCW and MMCW soils in growing season were 0.635 and 0.687 gN/m2, and the denitrification gaseous lost amounts were 0.617 and 0.405 gN/m2, respectively. In plant subsystem, the N was mainly stored in root and litter. Soil organic N was the main N storage of the two plant-soil systems and the proportions of it were 93.98% and 92.16%, respectively. The calculation results of N turnovers among compartments of TMCW and MMCW showed that the uptake amounts of root were 23.02 and 28.18 gN/(m2·a) and the values of aboveground were 11.31 and 6.08 gN/(m2·a), the re-translocation amounts from aboveground to root were 5.96 and 2.70 gN/(m2·a), the translocation amounts from aboveground living body to litter were 5.35 and 3.38 gN/(m2·a), the translocation amounts from litter to soil were larger than 1.55 and 3.01 gN/(m2·a), the translocation amounts from root to soil were 14.90 and 13.17 gN/(m2·a), and the soil (0-15cm) N net mineralization amounts were 1.94 and 0.55 gN/(m2·a), respectively. The study of N balance indicated that the two plant-soil systems might be situated in the status of lacking N, and the status might induce the degradation of C. angustifolia wetland.     

Imazaquin degradation and metabolism in a sandy loam soil amended with farm litters

Irnazaquin applied in legume crops has a long residual time in soil, which often impacts safety of the susceptible crops. To increase safety of imazaquin application, two composted litters, bovine manure （BM） and chicken manure （CM）, were used to determine their effects on imazaquin environmental behavior by incorporating each kind of manure into the tested sandy loam soil at 10% （w/w）. The degradation of imazaquin in BM- and CM-amended soil was about 2.4 and 1.5 times, respectively, faster than that in unamended soil. The half-lives of imazaquin in BM-amended soil varied between 6.7 and 15.4 d over the temperature range of 20 to 40℃, and the degradation rate constant （k） increased by a factor of about 1.5 for every 10℃ change. Higher mix ratio did not significantly increase the degradation, and the optimal active degradation of imazaquin was observed approximately at the mix ratio of 10：1 of soil to BM. The different moisture levels had negligible effect on imazaquin degradation. In both unamended and BM-amended treatments, two metabolites were observed at 5, 10 and 30 d after treatment. One metabolite at retention time （RT） of 8.4 rain was identified as 2-（4- hydroxyl-5-oxo-2-imidazolin-2-yl） quinoline acid, originating from the loss of isopropyl group and hydroxylation at the 4-position of imidazolinone ring. The other at RT of 12.9 rain was identified as quinoline-2,3-dicarboxylic anhydride, resulting from detachment of imidazolinone ring and the forming of dicarboxylic anhydride. This finding suggested that the addition of farm litters into soil might be a good management option since it can not only increase soil fertility but also contribute to increase safety of imazaquin application to the following susceptible crops.     

Organic matter and concentrated nitrogen removal by shortcut nitrification and denitrification from mature municipal landfill leachate

An UASB＋Anoxic/Oxic （A/O） system was introduced to treat a mature landfill leachate with low carbon-to-nitrogen ratio and high ammonia concentration. To make the best use of the biodegradable COD in the leaehate, the denitrifieation of NOx^--N in the reeireulation effluent from the elarifier was carried out in the UASB. The results showed that most biodegradable organic matters were removed by the denitrifieation in the UASB. The NH4^＋-N loading rate （ALR） of A/O reactor and operational temperature was 0.28- 0.60 kg NH4^＋-N/（m^3-d） and 17-29℃ during experimental period, respectively. The short-cut nitrification with nitrite accumulation efficiency of 90%-99% was stabilized during the whole experiment. The NH4^＋-N removal efficiency varied between 90% and 100%. When ALR was less than 0.45 kg NH4^＋-N/（m^3.d）, the NH4^＋-N removal efficiency was more than 98%. With the influent NH4^＋-N of 1200-1800 mg/L, the effluent NH4^＋-N was less than 15 mg/L. The shortcut nitrification and denitrifieation can save 40% carbon source, with a highly efficient denitrifieation taking place in the UASB. When the ratio of the feed COD to feed NH4^＋-N was only 2-3, the total inorganic nitrogen （TIN） removal efficiency attained 67%-80%. Besides, the sludge samples from A/O reactor were analyzed using FISH. The FISH analysis revealed that ammonia oxidation bacteria （AOB） accounted for 4% of the total eubaeterial population, whereas nitrite oxidation bacteria （NOB） accounted only for 0.2% of the total eubaeterial population.     

物质流指标下的工业经济解耦问题研究

随着经济的快速发展,资源约束下环境问题日益突出,生态文明建设要求社会经济系统在经济增长的同时,环境和资源日益改善以满足循环经济的发展需求。为改善经济增长与环境资源状况的耦合现状,需要分析工业经济增长与矿产资源消耗、固废及废气排放的耦合程度。本文基于低碳试点省市工业系统的化石能源、矿产资源消耗统计和CO2排放测算,确定各省市工业系统物质流输入输出指标,采用解耦权重图解法对主要指标的组成部分分别赋予权重,并结合指数时间序列分析各指标组成部分的解耦程度。结果表明,试点省市工业总产值的快速增长是以较高的碳排放为前提,并且碳排放对工业经济增长的解耦贡献逐年升高,控制碳排放的关键在于进一步优化工业能源消耗模式,提高能源利用效率,降低能源强度并适度引入清洁能源。因此应从能源消费结构优化、矿产资源利用率提升等方面积极转变发展方式,以达到碳排放、固体废弃物减排等目标,实现中国工业经济的绿色增长,保障生态文明建设的顺利进行。