莱州湾西南部岸线变迁对海域水动力影响的数值研究

20世纪70年代以来,盐田、养殖围堤、港口堤坝建设等开发活动使莱州湾西南部岸线变迁尤为显著,从而引起了海湾水动力环境的改变。为探究近50年莱州湾水动力环境对海湾西南部岸线变迁的响应,本文建立二维数值模型,研究莱州湾西南部3个时段岸线变迁对海湾潮流、纳潮量和水交换的影响。结果表明,1968－2020年莱州湾西南部流速变化以减小为主,流速变化较大的区域主要位于盐田或养殖围垦区和新建港口附近海域。近50年,莱州湾纳潮量呈逐年减小趋势,大潮、中潮、小潮和全潮平均纳潮量分别减少5.85%、7.28%、8.85%和6.47%,围填海是导致纳潮量减小的主要原因。1968－2010年莱州湾整体的水交换能力有所提高,2010－2020年则相差很小;从局部看,1990－2020年港口附近海域的水交换能力均显著降低。     

La-M-Co-O/堇青石催化剂的制备及催化氧化氯苯

采用柠檬酸络合法制备La-M-Co-O（M=Mn,Cr,Fe,Ni和Cu）/堇青石催化剂,运用BET,XRD,SEM,H₂-TPR和XPS技术对催化剂性能及微观结构进行表征分析,研究考察过渡金属掺杂,掺杂量以及焙烧温度等对催化剂催化氧化性能的影响.结果表明,随着催化剂焙烧温度升高至650℃时,催化剂表面所负载的活性氧化物颗粒最为分散,其氧化活性最佳,且当反应温度为350℃时,催化剂催化氧化氯苯转化率可达96.4%,究其原因是高温焙烧致使催化剂形成LaCoO₃钙钛矿型复合氧化物,其复合氧化物的晶体结构有利于催化剂催化氧化氯苯性能的提高.     

中国典型湖泊四大类抗生素污染特征

基于已有文献资料数据,以中国东部平原湖区（31个）,蒙新湖区（4个）,二龙湖,青海湖及抚仙湖共38个典型湖泊为研究对象,总结分析四大类常用抗生素（四环素类,磺胺类,喹诺酮类和大环内酯类）在湖泊水体和沉积物中的污染特征.结果表明,四大类抗生素污染在中国典型湖泊中普遍存在,其中水体中抗生素污染水平依次为磺胺类（2147ng/L） > 喹诺酮类（1458ng/L） > 四环素类（481ng/L） > 大环内酯类（205ng/L）,沉积物中抗生素的分布具有垂向差异特征,表层沉积物抗生素浓度高于深层沉积物.抗生素检出浓度在不同湖区间存在较大差异,其中东部平原湖区水体和沉积物中抗生素浓度显著高于其他湖区.相比入湖河流,湖区（如太湖贡湖湾和青海湖）水体中抗生素污染相对较高,表明湖区可能作为抗生素的汇集地.湖泊水体中的抗生素浓度分布呈现季节性差异,如太湖水体中抗生素浓度在春,夏及冬季高于秋季,而鄱阳湖,白洋淀和二龙湖在旱季（4月）高于雨季（8月）;而湖泊沉积物中抗生素季节性差异较不明显,这可能与抗生素在沉积物中的迁移性有关.     

沟塘水质及其周边浅层地下水PAHs的风险评价

为探讨农村居民区沟塘水质对周边浅层地下水的影响,在河南省某县选择典型沟塘,分别在枯水期和丰水期采集沟塘水和周边浅层地下水样品,采用高效液相色谱检测16种多环芳烃（PAHs）的含量,分别描述并比较枯丰水期PAHs的污染特征及其生态与健康风险.结果表明,枯水期沟塘水中BaP含量、∑PAHs、TEQ（BaP）含量和致癌性PAHs占比分别为0.911ng/L、29.3ng/L、1.64ng/L和28.1%,均低于丰水期;浅层地下水中各指标分别为5.37ng/L、291ng/L、12.5ng/L和25.9%,高于丰水期.枯丰水期沟塘水和浅层地下水中PAHs均主要源于生物质和煤炭燃烧.浅层地下水PAHs的含量与沟塘水具有关联性,即距离沟塘越近,PAHs含量越高,枯水期的关联性低于丰水期.饮用浅层地下水致PAHs暴露的累积非致癌风险HQ为2.21x10^-3;累积致癌风险R为1.56x10^-6,72.0%成人R大于1x10^-6,枯水期BaA、BbF和InP对成人致癌风险的贡献分别为72.1%、9.10%和4.80%.枯水期沟塘水PAHs总量为低等生态风险,丰水期为中等风险,不同沟塘其生态风险不同.纳污的C5沟塘水丰水期PAHs为高生态风险水平,BaA的贡献最大（占40.7%）;纳污和养殖的A2枯水期和C3沟塘水丰水期PAHs为中等风险2水平.综上,沟塘水PAHs与周边浅层地下水具有关联性,枯水期沟塘水PAHs总量具有低生态风险,饮用周边浅层地下水的致癌风险高于1x10^-6.     

城市化影响杭州城市热环境的数值模拟研究

通过对城市区域的气候要素进行精细化数值模拟,可以研究城市化对城市热环境的重要影响.利用WRF/UCM模式,以杭州为例,通过采用不同的下垫面土地利用分类数据,分析量化历史城市化进程对月尺度城市热环境的影响,并进一步设计了敏感性模拟试验,研究杭州地区在理想化条件下城区面积增加约2倍时,城市热环境的变化情况.模拟结果表明,杭州地区在2010~2017年的城市化进程中,城区面积约增加了1倍,导致8月热岛强度等级高于”无”（Ht>0.5℃）的区域扩大了91%,且主城区的2m平均气温增加了0.4℃,但中心城区热岛强度等级没有明显提升.杭州城区面积在2017年基础上约增加2倍时,8月热岛强度等级高于”无”的区域扩大157%,1846.4km²的中心城区热岛强度等级由”弱”或”无”（Ht≤1.5℃）提升为”中等”（1.5相似文献   

Marine aquaculture regulates dissimilatory nitrate reduction processes in a typical semi-enclosed bay of southeastern China

Marine aquaculture in semi-enclosed bays can significantly influence nutrient cycling in coastal ecosystems. However, the impact of marine aquaculture on the dynamics of dissimilatory nitrate reduction processes (DNRPs) and the fate of reactive nitrogen remain poorly understood. In this study, the rates of DNRPs and the abundances of related functional genes were investigated in aquaculture and non-aquaculture areas. The results showed that marine aquaculture significantly increased the denitrification (DNF) and dissimilatory nitrate reduction to ammonium (DNRA) rates and decreased the rate of anaerobic ammonium oxidation (ANA), as compared with non-aquaculture sites. DNF was the dominant pathway contributing to the total nitrate reduction, and its contribution to the total nitrate reduction significantly increased from 66.72% at non-aquaculture sites to 78.50% at aquaculture sites. Marine aquaculture can significantly affect the physicochemical characteristics of sediment and the abundances of related functional genes, leading to variations in the nitrate reduction rates. Although nitrate removal rates increased in the marine aquaculture area, ammonification rates and the nitrogen retention index in the aquaculture areas were 2.19 and 1.24 times, respectively, higher than those at non-aquaculture sites. Net reactive nitrogen retention exceeded nitrogen removal in the aquaculture area, and the retained reactive nitrogen could diffuse with the tidal current to the entire bay, thereby aggravating N pollution in the entire study area. These results show that marine aquaculture is the dominant source of nitrogen pollution in semi-enclosed bays. This study can provide insights into nitrogen pollution control in semi-enclosed bays with well-developed marine aquaculture.     

Impact of meteorological condition changes on air quality and particulate chemical composition during the COVID-19 lockdown

Stringent quarantine measures during the Coronavirus Disease 2019 (COVID-19) lockdown period (January 23, 2020 to March 15, 2020) have resulted in a distinct decrease in anthropogenic source emissions in North China Plain compared to the paralleled period of 2019. Particularly, 22.7% decrease in NO₂ and 3.0% increase of O₃ was observed in Tianjin, nonlinear relationship between O₃ generation and NO₂ implied that synergetic control of NO_x and VOCs is needed. Deteriorating meteorological condition during the COVID-19 lockdown obscured the actual PM_2.5 reduction. Fireworks transport in 2020 Spring Festival (SF) triggered regional haze pollution. PM_2.5 during the COVID-19 lockdown only reduced by 5.6% in Tianjin. Here we used the dispersion coefficient to normalize the measured PM_2.5 (DN-PM_2.5), aiming to eliminate the adverse meteorological impact and roughly estimate the actual PM_2.5 reduction, which reduced by 17.7% during the COVID-19 lockdown. In terms of PM_2.5 chemical composition, significant NO₃^? increase was observed during the COVID-19 lockdown. However, as a tracer of atmospheric oxidation capacity, odd oxygen (O_x = NO₂ + O₃) was observed to reduce during the COVID-19 lockdown, whereas relative humidity (RH), specific humidity and aerosol liquid water content (ALWC) were observed with noticeable enhancement. Nitrogen oxidation rate (NOR) was observed to increase at higher specific humidity and ALWC, especially in the haze episode occurred during 2020SF, high air humidity and obvious nitrate generation was observed. Anomalously enhanced air humidity may response for the nitrate increase during the COVID-19 lockdown period.     

Fine particle-bound PAHs derivatives at mountain background site (Mount Tai) of the North China: Concentration, source diagnosis and health risk assessment

Ten nitrated polycyclic aromatic hydrocarbons (nPAHs) and 4 oxygenated polycyclic aromatic hydrocarbons (oPAHs) in fine particulate matter (PM_2.5) samples from Mount Tai were analyzed during summer (June to August), 2015. During the observation campaign, the mean concentration of total nPAHs and oPAHs was 31.62 pg/m³ and 0.15 ng/m³, respectively. Two of the monitored compounds, namely 9-nitro-anthracene (9N-ANT) (6.86 pg/m³) and 9-fluorenone (9FO) (0.05 ng/m³) were the predominant compounds of nPAHs and oPAHs, respectively. The potential source and long-range transportation of nPAHs and oPAHs were investigated by the positive matrix factorization (PMF) method and the potential source contribution function (PSCF) methods. The results revealed that biomass/coal burning, gasoline vehicle emission, diesel vehicle emission and secondary formation were the dominant sources of nPAHs and oPAHs, which were mainly from Henan province and Beijing-Tianjin-Hebei region and Bohai sea. The incremental life cancer risk (ILCR) values were calculated to evaluate the exposure risk of nPAHs and oPAHs for three group people (infant, children and adult), and the values of ILCR were 7.02 × 10^?10, 3.49 × 10^?9 and 1.41 × 10^?8 for infant, children and adults, respectively. All these values were lower than the standard of EPA (Environmental Protection Agency) (<10^?6), indicating acceptable health risk of nPAHs and oPAHs.     

Potential applications of porous organic polymers as adsorbent for the adsorption of volatile organic compounds

Volatile organic compounds (VOCs) with high toxicity and carcinogenicity are emitted from kinds of industries, which endanger human health and the environment. Adsorption is a promising method for the treatment of VOCs due to its low cost and high efficiency. In recent years, activated carbons, zeolites, and mesoporous materials are widely used to remove VOCs because of their high specific surface area and abundant porosity. However, the hydrophilic nature and low desorption rate of those materials limit their commercial application. Furthermore, the adsorption capacities of VOCs still need to be improved. Porous organic polymers (POPs) with extremely high porosity, structural diversity, and hydrophobic have been considered as one of the most promising candidates for VOCs adsorption. This review generalized the superiority of POPs for VOCs adsorption compared to other porous materials and summarized the studies of VOCs adsorption on different types of POPs. Moreover, the mechanism of competitive adsorption between water and VOCs on the POPs was discussed. Finally, a concise outlook for utilizing POPs for VOCs adsorption was discussed, noting areas in which further work is needed to develop the next-generation POPs for practical applications.