微污染水源水处理技术探析

近年来,我国不少地区饮用水水源水质日益恶化,水质净化面临新的问题。通过对微污染水源水处理技术的分析,阐明了微污染水处理的基本理论,探讨了强化传统处理工艺、预处理技术、深化处理技术的作用效果与机理,展望了我国饮用水源水处理发展趋势。     

一体化设备处理某乡镇微污染地下水工艺研究

针对乡镇地下水微污染的特点,研究石英砂一沸石过滤器、膜组件与紫外线消毒器一体化设备处理效果,当进水浊度在15—36NTU,出水浊度达0．2—0．5NTU,去除效率达98％-99．3％;进水氨氮浓度范围为0．4～1．4mg／L,反应3．5min后出水的氨氮浓度小于0．5mg／L;微生物指标去除率为100％。采用一体化设备处理乡镇微污染地下水可行。     

处理微污染河水的人工湿地中磷的去除特征及吸附形态分布

通过在野外条件下构建两座潜流人工湿地,考察了湿地对微污染水体中磷的净化效果,以及湿地填料对4种主要形态磷的吸附特征.结果表明,湿地对总磷(TP)的平均去除率在30％左右,颗粒性总磷(STP)去除比例略高于溶解性总磷(DTP).两个湿地中TP的出水负荷随其进水负荷的升高线性增大,而磷的单位面积去除负荷与进水负荷呈对数关系,迸水负荷超过1000 g·m-2·d-1后,去除负荷没有发生明显变化.4种主要形态磷的吸附量关系表现为钙镁磷(Ca/Mg-P,12582和11052 mg)＞铁铝磷(Fe/Al-P,5312和5750 mg)＞弱吸附磷(Plabile-P,2054和1207 mg)＞腐殖质磷(Humic-P,-362和-136 mg).湿地3层填料对Humic-P和Plabile-P的吸附能力有限,且伴有解吸现象,而Ca/Mg-P和Fe/Al-P的吸附主要发生在卵石和碎砖层,碎石层对湿地中磷的去除贡献较低.栽种植物对湿地中填料对磷的吸附影响较小.     

COVID-19管控期间气象条件变化对京津冀PM2.5浓度影响

2020年初新冠肺炎疫情（COVID-19）暴发后,中国多地实施了严格的管控措施,导致污染物排放量明显下降.但在减排实施的情况下,京津冀PM_2.5等污染物浓度较过去5 a同期却明显增长,出现了两次PM_2.5重度污染事件.利用欧洲中心ERA5再分析资料分析发现,相对于过去5 a, COVID-19管控期间京津冀地区的气象场表现为偏高的相对湿度、偏低的边界层高度和边界层内异常的辐合上升运动,有利于颗粒物的吸湿增长和二次转化,不利于污染物垂直方向上的扩散.此外,利用WRF-Chem模式开展敏感性试验发现,在京津冀中部地区气象场的变化导致2020年管控期间ρ(PM_2.5)升高了20～55μg·m^-3,升高比例高达60%～170%.进一步利用过程诊断分析法得出,增强的气溶胶化学过程和不利的湍流扩散条件是2020年COVID-19管控期间PM_2.5浓度升高的主要原因.在当今减排的大背景下,边界层高度和相对湿度的变化可能成为预报预测京津冀地区PM_2.5污染事件的重要指标...     

多种材料对水中氨氮的吸附特性

针对黑臭水体中氨氮难以去除的问题,选取沸石、麦饭石、硅藻土、膨润土和活性炭这5种材料,通过实验考察所选材料对水中氨氮的吸附性能.结果表明,准二级动力学方程更加适用于5种材料的数据拟合,得出最大吸附量分别为2. 067 3、0. 998 2、0. 758 0、1. 748 6和1. 016 0 mg·g~(-1),且接近实验值,因此化学吸附是主要的吸附方式;采用Langmuir和Freundlich等温方程对数据进行拟合,得出硅藻土更适合Langmuir等温方程,属于单层吸附,其他4种材料则更加适合Freundlich等温方程为多层分子吸附,且5种材料的吸附都为有利吸附;通过投加量实验得知,沸石、硅藻土、膨润土和活性炭对氨氮去除率随投加量增加而升高,最大去除率分别为100%、10. 46%、49. 25%和16. 87%,而麦饭石先升高后降低,投加量为0. 4g时,取得最大值为48. 85%;在p H为4～10,沸石和麦饭石吸附量先增加后减少,而硅藻土、膨润土和活性炭的吸附量缓慢升高; 5种材料氨氮解吸量随初始浓度升高而升高.     

气象水文因子对呼伦湖湿地区域植物气候生产潜力的影响

利用呼伦湖湿地50年的气象资料、水文资料和生态环境监测资料,采用迈阿密模型及回归统计分析方法,分析了气象水文因子对呼伦湖湿地区域植物气候生产潜力的影响,结果表明,①50年来该湿地植物气候生产潜力变化趋势总体为下降趋势,减少的气候倾向率为每10年157.7 kg·km-2,峰值时段为1970—1990年,两个谷值时段为1961—1969年、1991—2010年,最大值和最小值与降水量出现的最多值和最少值一一对应。②在15个气象水文因子中有年降水量、年蒸散量、生长季径流量、春季大风日数、水位、春季平均风速、年大风日数、水域面积8个因子达到显著性检验（P〈0.150～0.001）,上述8个因子的排序也是与湿地区域植物气候生产潜力相关程度由大到小的排序。综述表明,呼伦湖湿地区域呈暖干化趋势,并且干旱灾害比较严重,是限制气候生产潜力的重要原因。③气象水文因子协同作用对该湿地区域植物气候生产潜力的影响较大,复相关系数为-0.997,年蒸散量与年平均气温、年降水量、生长季径流量和水位因子对湿地区域植物气候生产潜力的贡献相反,随其减少或增加,湿地区域植物气候生产潜力变化率增加或减少149.7 kg·hm-2。可以看出,该湿地气象水文因子的匹配并不理想,暖干化趋势依然是制约该区光能利用率低下的重要原因。④该湿地区域植物现实的生产力远未达到气候生产潜力,约有近60%的潜力可以开发;光能利用率较小的主要原因：一是现有的生态保护、修复技术及管理水平还比较落后,二是该区域暖干化趋势显著;而提高气候资源利用率的有效途径是加大保护生态环境力度和积极实施人工增雨、节水灌溉工程。     

Rapid control of black and odorous substances from heavily-polluted sediment by oxidation: Efficiency and effects

Oxidants were proposed to rapidly control black and odorous substances in sediments. NaClO and KMnO₄ had excellent efficiency to remove black and odorous substances. NaClO dramatically accelerated the release of organics, NH₄⁺-N, P, and heavy-metals. Moderate oxidation had a limited effect on microbial communities. NaClO of 0.2 mmol/g was viewed to be the optimum option. The control of black and odorous substances in sediments is of crucial importance to improve the urban ecological landscape and to restore water environments accordingly. In this study, chemical oxidation by the oxidants NaClO, H₂O₂, and KMnO₄ was proposed to achieve rapid control of black and odorous substances in heavily-polluted sediments. Results indicate that NaClO and KMnO₄ are effective at removing Fe(II) and acid volatile sulfides. The removal efficiencies of Fe(II) and AVS were determined to be 45.2%, 94.1%, and 93.7%, 89.5% after 24-h exposure to NaClO and KMnO₄ at 0.2 mmol/g, respectively. Additionally, rapid oxidation might accelerate the release of pollutants from sediment. The release of organic matters and phosphorus with the maximum ratios of 22.1% and 51.2% was observed upon NaClO oxidation at 0.4 mmol/g. Moreover, the introduction of oxidants contributed to changes in the microbial community composition in sediment. After oxidation by NaClO and KMnO₄ at 0.4 mmol/g, the Shannon index decreased from 6.72 to 5.19 and 4.95, whereas the OTU numbers decreased from 2904 to 1677 and 1553, respectively. Comparatively, H₂O₂ showed a lower effect on the removal of black and odorous substances, pollutant release, and changes in sediment microorganisms. This study illustrates the effects of oxidant addition on the characteristics of heavily polluted sediments and shows that chemical oxidants may be an option to achieve rapid control of black and odorous substances prior to remediation of water environments.     

STABLE HYDROGEN AND OXYGEN ISOTOPE COMPOSITION OF PRECIPITATION IN NORTHEASTERN COLORADO1

ABSTRACT: Where data are available, hydrologic studies may use precipitation's stable oxygen and hydrogen isotope composition to investigate streamflow, ground water/surface water interaction, and ground water recharge. Paleoclimate studies utilize the δ¹⁸O_{precipitation}‐T_air relationship, in conjunction with lake sediments, fossils, or old ground waters, for example, to estimate pale‐otemperatures. Ecological studies utilize precipitation and soil water isotope composition to track moisture uptake in plants, and to trace species migration patterns. Such studies require that the isotopic composition of precipitation be known. Oxygen‐18 (δ¹⁸O) and deuterium (δ²H) data for precipitation are lacking in the semi‐arid portion of the north‐central U.S. Great Plains, and thus there is a need to establish additional meteoric water lines as isotope input functions across the region, as well as to develop better understanding of the isotopic climate linkages that control oxygen and hydrogen isotope ratios in precipitation. This study determined the δ¹⁸O and δ²H composition of precipitation in the Pawnee Grasslands of northeastern Colorado from 1994 through 1998 using archived National Atmospheric Deposition Program samples. The resulting local water line follows the relationship δ²H = 7.86 δ¹⁸O‐7.66, and the data show a δ¹⁸O_weekly ‐ T_weekly relationship of δ¹⁸O = 0.560‐T (°C)‐18.8.     

THE FLOOD OF '96 AND ITS SOCIOECONOMIC IMPACTS IN THE SUSQUEHANNA RWER BASIN1

ABSTRACT: The meteorology flood hydroclimatolog and socioeconomic impacts of the Flood of January 1996 in the Susquehanna River Basin are explored. The analysis explains how an unusual storm system brought high humidities, high temperatures, strong winds, and heavy rain to the basin. The rapid melt of the deep snowpack, combined with the heavy rainfall, produced the sudden release of large volumes of water. Because the ground surface was frozen or saturated, this water moved primarily as overland flow. Thus, the flood waters were not restricted to areas immediately adjacent to stream channels and, consequently, some of the largest impacts were on people, property, and infrastructure in areas not normally prone to flooding. Socioeconomic patterns of flooding over time and space are investigated to put this flood into context and to highlight its impacts. The analysis concludes that if such overland flooding is a more common feature of climate change, then the current vulnerability to this form of flooding and its economic implications must be considered carefully.     

RAINFALL POINT INTENSITIES IN AN AIR MASS THUNDERSTORM ENVIRONMENT: WALNUT GULCH,ARIZONA1

ABSTRACT: Point rainfall intensities for a given return period are often used to formulate design storms for rainfall/runoff models to simulate design floods. These design floods are in turn used to design bridges, culverts, and a variety of drainage and flood control structures. The projected rapid growth in the southwestern United States will require very substantial monetary investments in drainage infrastructure. Accurate estimates of point rainfall intensities are critical to ensure both safe designs while not wasting dollars in overdesign. Rainfall point intensities (accumulated rainfall depth over a specified duration) for 5‐, 15‐, 30‐, and 60‐minute durations for the 2‐, 5‐, 10‐, 25‐, 50‐, and 100‐year return periods were determined for southeast Arizona. Thirty‐five years of rainfall record (1961 to 1995) were used in this study. The records came from 20 stations that were grouped into five sets of four independent stations to extend the rainfall records. The stations are in the USDA‐ARS Walnut Gulch Experimental Watershed (WGEW), which is representative of large portions of the Southwest whose runoff generation is dominated by air‐mass thunderstorms. The 5‐, 15‐, 30‐, and 60‐minute maximum intensities per year followed log‐normal distributions. The mean point rainfall intensities of the five sets of gages are very close (between 0 and 11 percent) to the NOAA values of the 5‐, 15‐, 30‐, and 60‐minute durations for all return periods. Much larger differences between the mean point rainfall intensities for all durations were found when these results were compared to those of a previous study done with a shorter rainfall record (between 14 and 33 percent for the 25‐, 50‐, and 100‐year return‐periods). The difference between the largest and the smallest values of point rainfall intensities recorded by each group, for all durations, usually increases as the return period increases.