长江河口水体有机污染物现状分析

对枯水期和丰水期长江河口区5个断面不同深度水样进行检测,共检出有机物200余种,其中定量检出的有机物达53种,有36种属美国EPA控制的有毒有机化合物,列入中国环境优先控制污染物黑名单的有16种.枯水期N-二甲基亚硝胺含量较高,最高值约为1.2 mg·L-1.丰水期2,4-二硝基酚、邻苯二甲酸二丁基苯基酯含量较高,最高值分别约为1.3和1.0 mg·L-1.底层水中有机污染物浓度高于表层和中层.     

电催化氧化降解大气中甲醛的研究

将有机废气通过高效微孔曝气转移到液相,采用活性碳纤维作为电极,研究不同鼓气速率和不同电压对处理效果的影响.结果表明,本方法适用于低浓度高气量有机废气的处理.在实验范围内,当曝气速率为20L·h-1,外加电压为5V的条件下,处理速率最稳定.     

集约化蔬菜种植区地下水中反硝化细菌的分离鉴定

从研究我国典型集约化蔬菜种植区地下水中硝酸盐的来源和浓度人手,进行富集、培养、分离、纯化,筛选出一株具有反硝化作用的菌株,通过形态学、革兰氏染色结合16SrDNA序列同源性分析鉴定,其鉴定结果为农杆菌(Agrobacterium sp.).该研究为开展地下水硝酸盐污染的生物修复储备宝贵的菌种资源,为地下水中硝酸盐污染的原位微生物修复和相关污水的生物处理提供微牛物基础,对于经济、有效的解决地下水硝酸盐污染和水资源短缺的问题有着十分重要的意义.     

基于熵权综合健康指数法的瀛湖水生态系统健康评估

瀛湖是南水北调丹江口水库重要的水源涵养区,承担着丹江口水库60%的供水量,又是沿线乡镇和安康市城区饮用水水源地。在充分调查的基础上,采用综合健康指数法对1986—2012年之间瀛湖的水生态系统健康状况进行了评估,结果表明,1986—2005年,瀛湖水生态系统健康指数呈逐渐下降趋势,健康状态由健康降至一般病态;2005—2012年之间,瀛湖水生态系统健康指数总体呈上升趋势,健康状态除2010年为一般病态外,其余均为亚健康状态。     

外源有机酸对小飞扬草(Euphorbia thymifolia L.)修复镉污染土壤的影响

植物修复有许多优点,但当用于重金属含量较高的土壤时,通常修复效率较低。研究了添加外源柠檬酸、草酸、苹果酸对镉超积累植物小飞扬草(Euphorbia thymifolia L.)富集Cd的影响,以及3种外源有机酸对土壤pH、Cd形态及小飞扬草根系生理生化特性的影响,探讨利用有机酸强化小飞扬草修复镉污染土壤的可能性及其作用机制。结果表明,土壤Cd含量为247 mg/kg时,种植15 d后,3种有机酸均提高了小飞扬草根和地上部Cd含量,强化效果:草酸>柠檬酸>苹果酸,10 mmol/kg草酸的加入使小飞扬草地上部分Cd含量达最大值77.21 mg/kg,比对照组提高87.72%。加入有机酸使土壤pH从7.65下降至6.01~7.45,BCR三步提取法分析土壤Cd形态结果表明,酸溶态Cd含量增加,残渣态Cd含量减小。加入20 mmol/kg苹果酸降低了根系的活力和ATP酶活性,根细胞膜透性与对照组无显著性差异,而加入5、10和20 mmol/kg的柠檬酸、草酸和5、10 mmol/kg的苹果酸均显著增加了小飞扬草根系的活力和ATP酶活性,减小了根细胞膜透性。说明添加3种外源有机酸能强化小飞扬草修复Cd污染土壤,利用外源有机酸很有可能成为提高重金属污染土壤植物修复效率的有效途径。     

接种内外源微生物菌剂对堆肥效果的影响

在严格控制堆肥条件的堆肥反应器中,以鸡粪为堆肥基础原料,内源微生物M37和外源微生物VT为接种剂,研究了堆肥过程中温度、氧气浓度、C/N、水溶性碳(WSC)、发芽指数(GI)以及蛋白酶和脱氢酶的活性动态变化.结果表明,接种M37后,堆肥升温速度加快,且升温期氧气浓度下降速度最快.接种VT后能够增加堆肥高温期的温度,且高温期氧气浓度最低.接种内外源微生物菌剂,C/N下降速度快,WSC浓度相对高.堆肥结束时,GI值显著高于CK,有利于加快堆肥腐熟进程.M37有利于堆肥升温期的蛋白酶和脱氢酶的积累,在高温期,VT处理的蛋白酶和脱氢酶活性最强,促进堆肥的氧化还原反应.     

有色金属企业的安全管理

近年来，我国国内有色金属产量和对矿产品需求量快速增长。10种有色金属产量已从1980年的124．8万吨发展到2008年的产量为2，519万吨，增长了20倍多，并从2002年起，连续六年产量位居世界第一；预计到2020年10种有色金属需求总量为3000万吨。     

CO2 dynamic of Lake Donghu highlights the need for long-term monitoring

Environmental Science and Pollution Research - Inland freshwater lakes have been widely considered as significant sources of CO2 to the atmosphere. However, long-term measurements of CO2 dynamics...     

On the effect of Fe(III) on proliferation of Microcystis aeruginosa at high nitrate and low chlorophyll condition

The impact of Fe concentrations on the growth of Microcystisaeruginosa in aquatic systems under high nitrate and low chlorophyll conditions was studied. The responses of cell density, total and cell chlorophyll-a intracellular Fe content and organic elemental composition of M. aeruginosa to different concentration gradients of Fe(III) in the solutions were analysed. The results showed that the proliferation speeds of M. aeruginosa were: (1) decelerated when the Fe(III) concentration was lower than 50 μg/L in the solutions, (2) promoted and positively related to the increase of Fe(III) concentration from 100 to 500 μg/L in the solutions over the experimental period, and (3) promoted in the early stage but decelerated in later stages by excess adsorption of Fe by cells when the Fe(III) concentration was higher than 500 μg/L in the solutions. The maximum cell density, total and cell chlorophyll-a were all observed at 500 μg Fe(III)/L concentration. The organic elemental composition of M. aeruginosa was also affected by the concentration of Fe(III) in the solutions, and the molecular formula of M. aeruginosa should be expressed as C_7–7.5H₁₄O_0.8–1.3N_3.5–5 according to the functions for different Fe(III) concentrations. Cell carbon and oxygen content appeared to increase slightly, while cell nitrogen content appeared to decrease as Fe(III) concentrations increased from 100 to 500 μg/L in the solutions. This was attributed to the competition of photosynthesis and nitrogen adsorption under varying cell Fe content.     

Effects of Cu2+ and humic acids on degradation and fate of TBBPA in pure culture of Pseudomonas sp. strain CDT

Soil contamination with tetrabromobisphenol A(TBBPA) has caused great concerns;however, the presence of heavy metals and soil organic matter on the biodegradation of TBBPA is still unclear. We isolated Pseudomonas sp. strain CDT, a TBBPA-degrading bacterium, from activated sludge and incubated it with ~(14)C-labeled TBBPA for 87 days in the absence and presence of Cu~(2+)and humic acids(HA). TBBPA was degraded to organic-solvent extractable(59.4% ± 2.2%) and non-extractable(25.1% ± 1.3%) metabolites,mineralized to CO_2(4.8% ± 0.8%), and assimilated into cells(10.6% ± 0.9%) at the end of incubation. When Cu~(2+)was present, the transformation of extractable metabolites into non-extractable metabolites and mineralization were inhibited, possibly due to the toxicity of Cu~(2+)to cells. HA significantly inhibited both dissipation and mineralization of TBBPA and altered the fate of TBBPA in the culture by formation of HA-bound residues that amounted to 22.1% ± 3.7% of the transformed TBBPA. The inhibition from HA was attributed to adsorption of TBBPA and formation of bound residues with HA via reaction of reactive metabolites with HA molecules, which decreased bioavailability of TBBPA and metabolites in the culture. When Cu~(2+)and HA were both present, Cu~(2+)significantly promoted the HA inhibition on TBBPA dissipation but not on metabolite degradation. The results provide insights into individual and interactive effects of Cu~(2+)and soil organic matter on the biotransformation of TBBPA and indicate that soil organic matter plays an essential role in determining the fate of organic pollutants in soil and mitigating heavy metal toxicity.