沈阳市郊区环境空气中醛酮类化合物的污染特征与来源分析

为探究沈阳市郊区环境空气中醛酮类化合物的污染特征,于2017年8月24日—9月2日采用2,4-二硝基苯肼固相吸附/高效液相色谱方法对沈阳市郊区醛酮类化合物进行观测分析,利用美国环境保护局推荐的人体健康风险评价方法对部分有毒有害醛酮类化合物的人体健康风险进行了评价,并利用比值法对醛酮类化合物的来源进行了初步分析.结果表明:醛酮类化合物质量浓度日均值范围为23.16~38.38 μg/m3;质量浓度最高的4种醛酮类化合物依次是丙酮、甲醛、正丁醛和乙醛,其质量浓度日均值的平均值分别为8.71、5.90、5.48和2.95 μg/m3.对·OH消耗速率(L_OH)贡献较大的醛酮类化合物物种是正丁醛、甲醛和乙醛,臭氧生成潜势贡献(OFP)较大的醛酮类化合物物种是甲醛、正丁醛和乙醛,在研究区影响醛酮类化合物光化学反应活性的物种主要是甲醛、乙醛和正丁醛.研究区观测期间,环境空气中甲醛和乙醛的致癌性风险值分别为1.18×10-5和5.91×10-6,对暴露人群存在潜在的致癌风险;乙醛的非致癌风险值为0.05,对暴露人群不存在非致癌风险.在研究区的一次臭氧轻度污染过程期间,环境空气中的甲醛和乙醛受天然源排放的挥发性有机物二次转化的影响减弱,甲醛、乙醛和丙酮受到炼焦工业和机动车等人为源排放的影响增强,而正丁醛主要受当地精细化工产业排放的影响.研究显示,沈阳市应加大对炼焦工业、精细化工和机动车来源排放醛酮类化合物的管制,以降低环境空气中活性醛酮类化合物及有毒有害醛酮类化合物的浓度.      

Impact of human activities on the quality of river water: The case of Evrotas River catchment basin,Greece

The impact of point (domestic and industrial effluents) and non-point (agricultural land runoff) pollution sources on the quality of the receiving waters of the Evrotas River (Laconia, Greece) was investigated during a monitoring study from August 1991 to August 1992. The part of the river which was located near the city of Sparta was seasonally influenced by the discharge of effluents from orange juice plants (operating during winter) and by the discharge of septage for the emptying of cesspools which are serving part of the city. The low dilution of incoming pollutants (septage) during the low water flow in summer lead to the decreasing self-purification capacity of the river and the development of septicity conditions in some of its parts. In the vicinity of intensively cultivated areas, the high concentrations of nitrogen and phosphorus which were detected in the river water during winter and spring may be partly attributed to the leaching of the applied fertilizers because of nirogen mobilization and soil erosion, following the season's precipitations. The protection of the Evrotas River water Quality must therefore include adequate treatment of the septage produced in the area, as well as the construction of wastewater treatment plants for the major industries of the area. The non-point pollution could be controlled by the restoration of the Evrotas riparian vegetation, together with a more rational use of fertilizers in the area.     

我国大气污染治理历程回顾与展望

大气污染防治工作是我国生态环境保护的重要组成部分,并随社会经济发展过程中出现的主要大气环境问题的演变而不断深化。几十年来,我国在大气污染控制和空气质量管理方面做了大量的工作并取得了显著成效。本文在系统回顾我国大气污染治理历程基础上,展望提出新时期推进我国大气污染治理创新思路。自20世纪70年代以来,我国大气污染治理随着社会经济发展和生态环境保护事业发展主要经历了消烟除尘构建大气环境容量理论(1972—1990年)、分区管控防治酸雨和二氧化硫污染(1991—2000年)、总量控制二氧化硫排放量见顶下降(2001—2010年)、攻坚克难打赢蓝天保卫战(2011—2020年)四个阶段。当前,在习近平生态文明思想指导下,在绿色发展、低碳发展、高质量发展推动下,在新旧动能转换带来产业结构、能源结构、交通运输结构进一步调整和优化的情况下,更先进的大气污染控制技术为大气污染减排提供了更强大的动力,生态环境治理体系和治理能力现代化建设为空气质量的持续改善提供了坚实保障。本文提出未来我国大气污染治理创新思路:生态优先、绿色发展,进一步调整产业结构,实现高质量发展;清洁高效,低碳少污,进一步调整能源结构,提升清洁能源、新能源和可再生能源供给能力;问题导向、目标引领,弄清大气污染来源成因,为科学治污提供坚实基础;清洁生产,全程控制,显著减少污染物的产生量和排放量;属地责任,联防联控,改善局地质量,降低区域间相互影响;智慧监控,数据归真,强化污染源监管。     

欧拉观测的大气扩散参数计算方法探析及应用

根据湍流扩散统计理论，讨论了利用欧拉观测的风速资料求解正态扩散模式中大气扩散参数的计算方法及其实现，并以海南洋埔开关区各稳定度大气扩散参数的计算为实例作了分析。     

Impacts of climate change on the hydrology of two Natura 2000 sites in Northern Greece

Greece is included among the most vulnerable regions of Europe by climate change on account of higher temperature and reduced rainfall in areas already facing water scarcity. With respect to wetland systems, many ephemeral ones are expected to disappear and several permanent to shrink due to climate change. As regards two specific wetlands of Greece, the change in hydroperiod of Cheimaditida and Kerkini lakes due to climate change was studied. Lakes’ water balance was simulated using historical climate data and the emission scenarios Α1Β for the period 2020–2050 and Α1Β and Α2 for the period 2070–2100. Future climate scenarios, based on emission scenarios A1B and A2, were provided in the context of the study of Climate Change Impacts Study Committee. The surface area of Lake Cheimaditida will undergo a substantial decrease, initially by 20 % during the period 2020–2050 and later until 37 % during the period 2070–2100. In Lake Kerkini, the surface area will decrease, initially by 5 % during the period 2020–2050 and later until 14 % during the period 2070–2100. Climate change is anticipated to impact the hydroperiod of the two wetlands, and the sustainable water management is essential to prevent the wetland’s biodiversity loss.