基于水热因子波动的呼伦贝尔草原产草量模型

基于多年气象资料(温度和降水量)和产草量监测数据,采用相关分析、主成分分析和回归分析等方法,构建呼伦贝尔草原产草量与气象因子统计学模型,并对二者之间的关系进行了分析.结果表明:利用水热波动因子建立的多项式回归模型具有较好的拟合效果,所建立的呼伦贝尔草原产草量预测模型为y=100.209+1.6410x-0.00559x2.F值显著性检验表明,其复相关系数R2=0.4713,F=8.0239(P=0.0033),在α=0.01水平上显著.利用1989─2009年呼伦贝尔草原产草量数据进行模型精度检验,模型预测精度在85%以上.该预测模型具有选用参数易得、易于代入遥感数据中进行栅格计算、精度高于基于植被指数预测模型等特点.     

Changes in functional structure of soil bacterial communities due to fungicide and insecticide applications in canola

The fungicide vinclozolin and insecticide λ-cyhalothrin are widely used to control canola (Brassica spp.) diseases and insect pests, respectively, in Canada. We investigated non-target effects of these pesticides, applied at recommended rates, on soil microbial biomass, functional bacterial diversity and functional community structure of soil bacteria (by evaluating patterns of C substrate utilization) in canola rhizosphere and bulk soil at three locations in Alberta from 2002 to 2004. Experimental treatments were (a) untreated control, (b) vinclozolin fungicide foliar application, (c) λ-cyhalothrin insecticide foliar application, and (d) vinclozolin and λ-cyhalothrin applications. No significant pesticide effects on soil microbial biomass or functional bacterial diversity were observed, but the functional structures of soil bacteria were altered. In 1 of 12 cases, the control treatment had a different soil bacterial community structure from the 3 pesticide treatments. The fungicide treatment had different bacterial community structures from the control or insecticide treatments in 3 of 12 cases, the insecticide treatment had different community structures from the control or fungicide treatments in 4 of 12 cases, and the combined fungicide and insecticide treatment had different community structures from the other treatments in 3 of 12 cases. Therefore, evaluating soil bacterial functional structures revealed pesticide effects that were not detected when bacterial diversity or microbial biomass were measured in canola rhizosphere or bulk soil.     

生物质成型燃料生产应用技术及经济效益分析

介绍了目前国内外生物质燃料中的颗粒燃料、棒状燃料等生产技术及生物质燃料的应用技术;针对当前全球能源的严峻形势,对运用生物质成型燃料的生产应用技术作了具体的经济分析和应用对比。     

库布齐沙漠油蒿灌丛土壤呼吸速率时空变异特征研究

利用Li-840红外气体分析仪和Li-6400-09土壤呼吸气室组装而成的动态密闭土壤呼吸测定系统,于2006年生长季对内蒙古库布齐沙漠油蒿(Artemisia ordosica)生态系统2种不同类型土壤的土壤呼吸速率进行了野外测定,分析了日动态、季节动态及其对环境因子的响应,并阐述了油蒿灌丛空间异质性的特征.结果表明,油蒿灌丛的土壤呼吸速率日动态呈单峰曲线,在12:00左右有最大值.在适宜的水分和温度条件下,生长季里土壤呼吸速率在7～8月份出现最大值.土壤呼吸速率的季节动态与土壤含水量有显著的相关关系,表明水分是限制生长季干旱区灌丛土壤呼吸的最重要因子,分别可以解释油蒿冠幅下土壤和裸地的土壤呼吸速率2006年主要生长季节(5～9月)变化的75%和77%.油蒿灌丛土壤呼吸速率在空间尺度上存在着显著的异质性.油蒿冠幅覆盖下的土壤呼吸速率季节平均值为(155.58±15.20) mg·(m²·h)^-1,要显著地大于灌丛间裸地的数值(110.50±6.77) mg·(m²·h)^-1.2种不同类型土壤的土壤呼吸速率是由于根生物量的差异引起的,根生物量可以解释2006年生长季库布齐油蒿灌丛土壤呼吸速率空间异质性的43%.结果表明,在植被覆盖度异质性较大的灌丛生态系统中,要准确定量生态系统碳的释放时,必须充分考虑小尺度上土壤呼吸的空间异质性.     

活性炭滤池中微生物特征及其对溶解性有机碳的去除作用

采用异养菌总数计数（HPC）法检测了北京地区J水厂活性炭滤池中微生物量,并分析了活性炭滤池进出水中有机物的组成、活性炭的吸附作用及微生物作用对溶解性有机碳(DOC)去除的贡献率.结果表明,不同炭龄、不同运行周期活性炭滤池中的微生物量有显著的差异.由于溶解性可生物降解有机碳（BDOC）占溶解性有机碳（DOC）的比例较小,且受微生物数量、活性等因素的影响,微生物对DOC的去除效果极为有限,在1.5年和5年炭龄活性炭滤池中对DOC的去除率仅占总去除率的18.8%和26.4%.此外,微生物对较为敏感的嗅味物质2-MIB和geosmin去除作用也不显著,去除率在15%以下（初始浓度为100ng·L-1）;在使用5年活性炭滤池中,微生物对2-MIB和geosmin去除率为12%和14%,分别占总去除率的32%和29%.因此,北京地区地表水净水厂活性炭滤池中微生物对有机物控制的贡献率较低,对DOC的去除主要以活性炭的吸附为主.     

生物质热解焦油脱除方法研究进展

生物质热解焦油的产生不仅降低了热解效率,影响设备运行,更危害着人类健康。通过介绍生物质热解焦油的特性及危害、对比分析目前各种不同除焦方法(文丘里法、旋风分离法、电捕焦法、高温裂解法和催化裂解法)的特点及应用前景,得出采用多种方法组合的形式进行联合除焦可显著提高焦油脱除效率。寻找用于湿法除焦的可再生利用的有机溶剂,开发经济、高效、长寿命的催化剂将成为生物质热解焦油脱除技术开发的重点。     

湿式电除尘器用于生物质气化燃气除尘的实验研究

生物质粉尘是生物质气化燃气中主要的杂质之一,其清除效果对生物质气化发电机组的安全运行有着重要的影响。以湿式电除尘装置作为试验平台,研究了生物质粉尘的特性和不同影响因素下湿式电除尘器的除尘效率,并对干法、湿法除尘效率进行对比。研究结果表明:生物质粉尘主要含C、O、Mg、Al、Si、K、Ca、Fe等元素,中位径为26.05μm。在相同条件下,除尘效率随着水压的增大而逐渐增大,当增加到0.4 MPa以后,无较大变化,除尘效率随着电场风速、焦油浓度的增加而减少,在洗涤水中添加少量的碱液有利于除尘。采用极配型式为RS二刺芒刺线配480C型板,当水压为0.4 MPa、电场风速为1.0 m/s,除尘效率可达99.21%。     

串叶松香草生物量和营养成分动态及其对土壤理化性质的影响

田间试验和化学分析结果表明,串叶松香草两个品种４个生育期的茎、叶产量均以Ａ型＞Ｂ型,在３ａ内串叶松香草产量随生长年限增加,且以Ａ型品种产量高．串叶松香草３个生育期叶片氨基酸和蛋白质含量高于茎,并以Ａ型品种现蕾期为最高;两个品种氨基酸组分以Ａｓｐ、Ｇｌｕ、Ｌｅｕ和Ｌｙｓ含量高,各生育期氨基酸组分含量变化规律不同．串叶松香草的粗脂肪、Ｃａ、Ｐ和灰分含量以叶＞茎,而粗纤维和可溶性糖含量却以茎中较高．除粗纤维外,其余饲用成分含量均随生育期的出现而呈递降之趋势．串叶松香草现蕾期Ｎ、Ｋ含量和莲座期Ｐ含量达最高．种植３ａ后串叶松香草明显改善土壤物理性质,提高土壤酶活性,明显降低土壤有效Ｎ、Ｐ和Ｋ含量     

A review of biomarker compounds as source indicators and tracers for air pollution

An overview of the application of organic geochemistry to the analysis of organic matter on aerosol particles is presented here. This organic matter is analyzed as solvent extractable bitumen/ lipids by gas chromatography-mass spectrometry. The organic geochemical approach assesses the origin, the environmental history and the nature of secondary products of organic matter by using the data derived from specific molecular analyses. Evaluations of production and fluxes, with cross-correlations can thus be made by the application of the same separation and analytical procedures to samples from point source emissions and the ambient atmosphere. This will be illustrated here with typical examples from the ambient atmosphere (aerosol particles) and from emissions of biomass burning (smoke). Organic matter in aerosols is derived from two major sources and is admixed depending on the geographic relief of the air shed. These sources are biogenic detritus (e.g., plant wax, microbes, etc.) and anthropogenic particle emissions (e.g., oils, soot, synthetics, etc.). Both biogenic detritus and some of the anthropogenic particle emissions contain organic materials which have unique and distinguishable compound distribution patterns (C₁₄-C₄₀). Microbial and vascular plant lipids are the dominant biogenic residues and petroleum hydrocarbons, with lesser amounts of the pyrogenic polynuclear aromatic hydrocarbons (PAH) and synthetics (e.g., chlorinated compounds), are the major anthropogenic residues. Biomass combustion is another important primary source of particles injected into the global atmosphere. It contributes many trace substances which are reactants in atmospheric chemistry and soot paniculate matter with adsorbed biomarker compounds, most of which are unknown chemical structures. The injection of natural product organic compounds into smoke occurs primarily by direct volatilization/steam stripping and by thermal alteration based on combustion temperature. Although the molecular composition of organic matter in smoke particles is highly variable, the molecular tracers are generally still source specific. Retene has been utilized as a tracer for conifer smoke in urban aerosols, but is not always detectable. Dehydroabietic acid is generally more concentrated in the atmosphere from the same emission sources. Degradation products from biopolymers (e.g., levoglucosan from cellulose) are also excellent tracers. An overview of the biomarker compositions of biomass smoke types is presented here. Defining additional tracers of thermally-altered and directly-emitted natural products in smoke aids the assessment of the organic matter type and input from biomass combustion to aerosols. The precursor to product approach of compound characterization by organic geochemistry can be applied successfully to provide tracers for studying the chemistry and dispersion of ambient aerosols and smoke plumes. Presented at the 6th FECS Conference on Chemistry and the Environment, Atmospheric Chemistry and Air Pollution, August 26–28, 1998, Copenhagen.     

生物质燃烧对东南亚及中国南方对流层臭氧含量影响的模拟研究

利用区域气候和大气化学模式系统,对2000年春季生物质燃烧排放影响东南亚及中国南部地区对流层臭氧含量进行模拟研究.结果表明,春季东南亚和南亚的生物质燃烧不仅影响源区对流层臭氧含量,而且对处于环流下游的中国南部地区也有显著作用;燃烧源区主要影响对流层低层,下游地区则影响对流层中低层.在源区引起的对流层臭氧总浓度增加达2.1×10^-1g/m²,对下游的中国南部地区增加量为9.0～12.0×10^-2g/m²;源区大气低层1000～900hPa的臭氧含量可增加36×10^-9m³/m³ 以上,而在中国南部750～700hPa高度上空的增加达15×10^-9m³/m³.