一种钢渣中氯离子的测定方法

利用蒸馏装置蒸出钢渣中的氯离子,使用硝酸汞滴定方法进行滴定,选用两种钢渣,在不同实验室分别进行了分析测定的比较和验证。结果表明:该方法简便易操作,重现性和准确性都比较高,作为钢渣中氯离子的测定是可行的。     

AFS断续流动氢化物原子荧光光度计测定饮用水中汞

介绍断续流动氢化物原子荧光光度计测定饮用水中汞的方法,研究了酸度,硼氢化钾浓度,灯电流,载气流速等对测定汞的影响.在优化的分析条件下,检测限为0.02ug/L,方法应用于水样中汞的测定,样品加标回收率在96.2％-102％之间,相对标准偏差为2.3％.方法具有操作简便,快速,灵敏度高等优点.     

走低碳发展之路实现生态文明之梦

低碳发展是一种以低耗能,低污染,低排放为特征的可持续发展模式。本文简述了走低碳发展之路既是可持续发展的要求,也是实现发展与环保双赢的保证。     

因子分析法在天津市主要河流水质污染程度综合评价中的应用

因子分析法作为一种常用的多元统计分析方法,可以有效地分析河流水质的变化趋势,准确地反映水体的污染状况和污染程度。本文将因子分析法应用于天津市主要河流的水质评价中,得出了天津市主要河流水质状况的综合评价结果和污染程度排名,该研究可为水环境管理与决策工作提供依据。     

PCBs降解菌的筛选及其降解特性研究

采用富集培养的方法从多氯联苯(PCBs)污染土壤中筛选到1株高效降解PCBs的细菌,命名为PS-11.经16S rDNA初步鉴定,此菌株属于嗜麦芽寡养单胞菌(Stenotrophomonas maltophilia).结果表明,菌株PS-11能够以PCBs作为唯一碳源生长并且能够降解PCBs,菌株PS-11对2 mg.L-1PCB52 4 d的降解率为31.1%,7 d的降解率可达52.9%;对难降解的高氯代多氯联苯PCB153 7 d的降解率为10.9%.此外,该菌株的环境耐受性比较好,在30℃、pH为7～9、PCB52浓度为2～10 mg.L-1的条件下生长较快、降解效果较好,尤其在pH 7、PCB52浓度为2 mg.L-1时降解率最高;碳源种类不同,菌株PS-11的生长能力也不同,其中在以蔗糖为碳源时PS-11的生长能力最强,以葡萄糖为碳源时PS-11的适应期最短,且蔗糖、葡萄糖和Tween-80均可提高PS-11对PCB52的降解率;同时菌株PS-11还可耐受一定浓度的重金属,其耐受性大小为Pb2+>Cd2+>Zn2+>Cu2+.     

Advances in air pollution control for key industries in China during the 13th five-year plan

Industrial development is an essential foundation of the national economy, but the industry is also the largest source of air pollution, of which power plants, iron and steel, building materials, and other industries emit large amounts of pollutants. Therefore, the Chinese government has promulgated a series of stringent emission regulations, and it is against this backdrop that research into air pollution control technologies for key industrial sectors is in full swing. In particular, during the 13th Five-Year Plan, breakthroughs have been made in pollution control technology for key industrial sectors. A multi-pollutant treatment technology system of desulfurization, denitrification, and dust collection, which applies to key industries such as power plants, steel, and building materials, has been developed. High-performance materials for the treatment of different pollutants, such as denitrification catalysts and desulfurization absorbers, were developed. At the same time, multi-pollutant synergistic removal technologies for flue gas in various industries have also become a hot research topic, with important breakthroughs in the synergistic removal of NO_x, SO_x, and Hg. Due to the increasingly stringent emission standards and regulations in China, there is still a need to work on the development of multi-pollutant synergistic technologies and further research and development of synergistic abatement technologies for CO₂ to meet the requirements of ultra-low emissions in industrial sectors.     

Assessing the role of mineral particles in the atmospheric photooxidation of typical carbonyl compound

Mineral particles are ubiquitous in the atmosphere and exhibit an important effect on the photooxidation of volatile organic compounds (VOCs). However, the role of mineral particles in the photochemical oxidation mechanism of VOCs remains unclear. Hence, the photooxidation reactions of acrolein (ARL) with OH radical (OH) in the presence and absence of SiO₂ were investigated by theoretical approach. The gas-phase reaction without SiO₂ has two distinct pathways (H-abstraction and OH-addition pathways), and carbonyl-H-abstraction is the dominant pathway. In the presence of SiO₂, the reaction mechanism is changed, i.e., the dominant pathway from carbonyl-H-abstraction to OH-addition to carbonyl C-atom. The energy barrier of OH-addition to carbonyl C-atom deceases 21.33 kcal/mol when SiO₂ is added. Carbonyl H-atom of ARL is occupied by SiO₂ via hydrogen bond, and carbonyl C-atom is activated by SiO₂. Hence, the main product changes from H-abstraction product to OH-adduct in the presence of SiO₂. The OH-adduct exhibits a thermodynamic feasibility to yield HO₂ radical and carboxylic acid via the subsequent reactions with O₂, with implications for O₃ formation and surface acidity of mineral particles.     

Competing pathways of cresol formation in toluene photooxidation: OH-toluene adducts react with NO2 or with O2?

Methyl-hydroxy-cyclohexadienyl radicals (OTAs) are the key products of the photooxidation of toluene, with implications for the fate of toluene. Hence, we investigated the photooxidation mechanisms and kinetics of three main OTAs (o-OTA, m-OTA, and p-OTA) with NO₂ using quantum chemical calculations as well as the fate of OTAs under the different concentration ratios of NO₂ and O₂. The mechanism results show that the pathway of H-abstraction by NO₂ to anti-HONO (anti-H-abstraction) is more favorable than the syn-H-abstraction pathway, because the strong interaction between OTAs and NO₂ is formed in the transition states of the anti-H-abstraction pathways. The branching ratios of the anti-H-abstraction pathways are more than 99% in the temperature range of 216−298 K. The total rate constant of the OTA-NO₂ reaction is 9.9 × 10⁻¹² cm³/(molecule∙sec) at 298 K, which is contributed about 90% by o-OTA + NO₂, and the main products are o-cresol and anti-HONO. The half-lives of the OTA-NO₂ reaction in some polluted areas of China are 35 times longer than those of the OTA-O₂ reaction. In the atmosphere, the NO₂- and O₂- initiated reactions of OTAs have the same ability to form cresols as [NO₂] is up to 142.1 ppmV, which is impossible to achieve. It implies that under the experimental condition, the [NO₂]/[O₂] should be controlled to be less than 7.8 × 10⁻⁵ to simulate real atmospheric oxidation of toluene. Our results reveal that for the photooxidation of toluene, the yield of cresol is not affected by the concentration of NO₂ under the atmospheric environment.     

Remediation of preservative ethylparaben in water using natural sphalerite: Kinetics and mechanisms

As a typical class of emerging organic contaminants(EOCs), the environmental transformation and abatement of preservative parabens have raised certain environmental concerns. However, the remediation of parabens-contaminated water using natural matrixes(such as, naturally abundant minerals) is not reported extensively in literature. In this study, the transformation kinetics and the mechanism of ethylparaben using natural sphalerite(NS) were investigated. The results show that around 63% of ethy...     

Seasonal to sub-seasonal variations of the Asian Tropopause Aerosols Layer affected by the deep convection, surface pollutants and precipitation

The Asian Tropopause Aerosols Layer (ATAL) refers to an accumulation of aerosols in the upper troposphere and lower stratosphere during boreal summer over Asia, which has a fundamental impact on the monsoon system and climate change. In this study, we primarily analyze the seasonal to sub-seasonal variations of the ATAL and the factors potentially influencing those variations based on MERRA2 reanalysis. The ability of the reanalysis to reproduce the ATAL is well validated by CALIPSO observations from May to October 2016. The results reveal that the ATAL has a synchronous spatiotemporal pattern with the development and movement of the Asian Summer Monsoon. Significant enhancement of ATAL intensity is found during the prevailing monsoon period of July–August, with two maxima centered over South Asia and the Arabian Peninsula. Owing to the fluctuations of deep convection, the ATAL shows an episodic variation on a timescale of 7–12 days. Attribution analysis indicates that deep convection dominates the variability of the ATAL with a contribution of 62.7%, followed by a contribution of 36.6% from surface pollutants. The impact of precipitation is limited. The ATAL further shows a clear diurnal variation: the peak of ATAL intensity occurs from 17:30 to 23:30 local time (LT), when the deep convection becomes strongest; the minimum ATAL intensity occurs around 8:30 LT owing to the weakened deep convection and photochemical reactions in clouds. The aerosol components of the ATAL show different spatiotemporal patterns and imply that black carbon and organic carbon come mainly from India, whereas sulfate comes mainly from China during the prevailing monsoon period.