中国竹林生态系统的碳储量

利用中国4次森林资源清查资料以及中国森林生态定位观测研究站(CFERN)的观测数据,估算了中国1977-2003年期间4个时期竹林生态系统的碳储量,并对其垂直分配结构特征、时空动态格局和贮碳潜力进行了分析.竹林的总碳储量结果为1977-1981年期间537.6Mt C,1984-1988年期问598.61Mt C,1994-1998年期间710.14 Mt C,1999-2003年期间837.92Mt C,期间浙江、江西、福建、湖南、广东和四川六省是中国竹林碳库的主要组成部分,占80.04%-83.13%.垂直分配结构基本相似,植被层占总碳储量的23.84%～24.49%,枯落物层占0.93%～0.96%,土壤层占的74.55%～75.23%.1999-2003年期间中国竹林生态系统碳素现存量为837.92 Mt C,10年后贮碳量将达到837.92 Mt C,并以C 54.81Mt·a-1.的平均积累速率递增.     

Ammonia emissions from different pig production scales and their temporal variations in the North China Plain

ABSTRACT

Pig production systems in China are shifting from small to industrial scale. Significant variation in housing ammonia (NH₃) emissions can exist due to differences in diet, housing design, and management practices. However, there is a knowledge gap regarding the impacts of farm-scale in China, which may be critical in identifying hotspots and mitigation targets. Here, continuous in-situ NH₃ concentration measurements were made at pig farms of different scales for sows and fattening pigs over periods of 3–6 days during two different seasons (summer vs. winter). For the sow farms, NH₃ emission rates were greater at the small farm (summer: 0.52 g pig^?1 hr^?1; winter: 0.21 g pig^?1 hr^?1) than at the large farm (summer: 0.34 g pig^?1 hr^?1; winter: 0.12 g pig^?1 hr^?1). For the fattening pig farms, NH₃ emission rates were greater at the large farm (summer: 0.22 g pig^?1 hr^?1; winter: 0.16 g pig^?1 hr^?1) than at the small farm (summer: 0.19 g pig^?1 hr^?1; winter: 0.07 g pig^?1 hr^?1). Regardless of farm scale, the NH₃ emission rates measured in summer were greater than those in winter; the NH₃ emission rates were greater in the daytime than at the nighttime; a positive relationship (R² = 0.06–0.68) was established between temperature and NH₃ emission rate, whereas a negative relationship (R² = 0.10–0.47) was found between relative humidity and NH₃ emission rate. The effect of farm-scale on indoor NH₃ concentration could mostly be explained by the differences in ventilation rates between farms. The diurnal variation in NH₃ concentration could be partly explained by ventilation rate (R² = 0.48–0.78) in the small traditional farms and by emission rate (R² = 0.26–0.85) in the large industrial farms, except for the large fattening pig farm in summer. Overall, mitigation of NH₃ emissions from sow farms should be a top priority in the North China Plain.

Implications: The present study firstly examined the farm-scale effect of ammonia emissions in the North China Plain. Of all farms, the sow farm was identified as the greatest source of ammonia emission. Regardless of farm scale, ammonia emission rates were observed to be higher in summer. Ammonia concentrations were mostly higher in the large industrial farms partly due to lower ventilation rates than in the small traditional farms.     

应用臭氧氧化技术深度处理油船含油压载水的实验研究

油船含油压载水大量排放入海会对海洋生态环境产生较大的危害。在研究中,通过强电离放电技术制取高浓度臭氧,应用臭氧氧化方法来深度处理含油压载水,模拟实验表明在臭氧投加浓度达到120mg/L,在较短的接触时间(2min)内,臭氧对不同浓度的含油压载水中的油去除率可达到50%以上,同时使芳香族类物质显著减少,降低含油污水的生物毒性,处理方法具有可观的应用前景。     

Fluorine distribution in aquatic environment and its health effect in the Western Region of the Songnen Plain, Northeast China

Endemic fluorosis was investigated and studied in the west region of the Songnen plain, Northeast China in 2001–2002. The results showed that the fluorine distribution in aquatic environment was that the fluorine concentrations in the lake water and unconfined ground water were higher than that in the river water and confined ground water. The lake water (Alkali lake) is connected with unconfined ground water. In unconfined ground water, from the east and southeast areas to the west and the northwest areas of the plain, fluorine concentration fluctuated with high and low alternatively. The fluorine in the water comes from the weathering of rocks and minerals in the mountains and hills around the Songnen Plain. The main influence factors of the fluorine distribution in aquatic environment are discussed. Unconfined ground water containing high fluorine is used as drinking water. In this region, the fluorine concentration in drinking water is evidently correlated to the morbidity of dental and skeletal fluorosis. High fluorine concentration in drinking water has endangered human health.     

安全氛围调查问卷的研究与设计

本文比较分析了国外具有代表意义的有关安全氛围调查问卷设计与应用的     

垃圾焚烧飞灰物理化学性质的实验研究

应用激光粒度粒形分析仪、灰熔融性测定仪、原子吸收光谱仪和XRD等仪器手段对国内2种垃圾焚烧飞灰的密度、颗粒特性、熔点、成分和晶相结构等物理化学性质进行了详细的研究。研究发现，2种灰样颗粒直径的数量积分分布非常接近，其中基本没有超过40 μm的颗粒。由于垃圾焚烧飞灰在化学成分上存在的差异导致了其熔点有很大的不同。此外，XRD结果显示不同来源的飞灰其晶相结构存在较大的差别，这可能与垃圾的来源和焚烧工艺以及烟气处理方法有关。实验结果为飞灰无害化低温烧结工艺的选择和运行参数的制定提供了依据。     

稻米和土壤中农美利残留量气相色谱分析方法的研究

建立了测定稻田土壤、稻米中农美利残留量的气相色谱分析方法。用配有NPD的气相色谱仪、DB-1301毛细管柱测定稻田土壤及稻米中农美利的残留量，最低检测浓度为0．01mg／kg、平均回收率为80．4％-99．8％，变异系数为6．3％-11．7％，均达到残留分析的要求。     

The practice and challenges of solid waste management in Singapore

This paper presents an overview of the current solid waste management situation in Singapore and provides a brief discussion of the future challenges. Singapore is a small island city-state with a large population, warm climate and high humidity. Over the past two to three decades, rapid industrialization and economic development have caused a tremendous increase in solid waste generation. The yearly disposed solid waste increased from 0.74 million tonnes in 1972 to 2.80 million tonnes in 2000. Solid waste management in Singapore has traditionally been undertaken by the Ministry of Environment (ENV), with the participation of some private sectors in recent years. The hierarchy of solid waste management in Singapore is waste minimization (reduce, reuse and recycle or so-called 3 Rs), followed by incineration and landfill. As land is extremely scarce and only one newly constructed offshore landfill site is available, solid waste incineration has been identified as the most preferred disposal method. Waste minimization, the utilization of incineration ashes, industrial waste management are regarded to be the major challenges in the future.     

P(AM-DMDAAC-VAM)共聚物的合成及其絮凝性能

以丙烯酰胺(AM)、二甲基二烯丙基氯化铵(DMDAAC)、乙酸乙烯酯(VAM)为单体,采用水溶液自由基胶束共聚合法合成了疏水缔合阳离子型共聚物P(AM-DMDAAC-VAM),并对其进行了红外光谱和核磁共振氢谱表征。实验结果表明:在P(AM-DMDAAC-VAM)加入量为14 mg/L、絮凝温度为30~60℃、硅藻土悬浊液pH为8~11时,P(AM-DMDAAC-VAM)对硅藻土悬浊液的絮凝效果最好,上清液透光率高达97.5%。