兼氧混合菌对亚甲基蓝废水生物降解实验研究

采用厦门某生物科技有限公司提供的兼氧混合菌为研究对象,利用相关设备进行中试实验,验证了该项技术的可行性。同时探究了重金属对该混合菌种生物降解能力的影响,通过中试实验研究后发现5mg/L的重铬酸钾和硫酸铜均对该混合菌种的生物降解能力有一定的影响,并且硫酸铜的影响大于重铬酸钾。此外该技术对甲基橙、刚果红废水也有一定的生物降解能力,这为兼氧混合菌用于印染废水处理提供了实验依据。     

重庆主城区次级河流表层沉积物重金属污染特征及风险评价

山地城市次级河流因季节性降雨容易导致沉积物中污染物形成"二次污染",沉积物可能具有重金属潜在生态风险.本文采集了重庆市主城区19条次级河流表层沉积物,分析了7种重金属元素(V、Cr、Ni、Cu、Zn、Cd和Pb)的污染水平,解析了重金属污染来源,并从流域层面评价次级河流表层沉积物重金属的潜在生态风险.结果表明,与背景值(中国土壤元素背景值)相比,除V外,其它6种重金属元素超标1.1~6.7倍.富集系数分析和主成分分析显示,沉积物中重金属V、Ni和Pb均未发生富集(富集系数小于1.5),且主要来源于自然源.Cd、Zn、Cu和Cr平均富集系数分别为6.63、2.31、1.90和1.40,均存在不同程度的富集;Cr、Zn和Cu主要来源于工业废水的排放.主城区次级河流表层沉积物重金属潜在生态风险指数RI值范围为77~382,均值为228,总体属于中等生态风险等级.空间分布上,重庆主城区西北部汇入嘉陵江的次级河流表层沉积物重金属表现出较高的生态风险,东南部汇入长江的次级河流表层沉积物表现为相对较低的风险.     

应用概率物种敏感度分布法研究太湖重金属水生生物水质基准

目前广泛使用的水质基准推导方法—物种敏感度分布法存在曲线拟合模型不确定、曲线拟合效果不佳、种内差异欠考虑、基准值不准确等诸多问题,概率物种敏感度分布法可有效解决上述问题。应用概率物种敏感度分布法构建了太湖水体中5种重金属Ag、Pb、Cd、Hg和Zn的概率物种敏感度分布曲线,在此基础上得到了保护水生生物的急性水质基准分别为1.079μg·L~(-1)、637.973μg·L~(-1)、19.465μg·L~(-1)、8.729μg·L~(-1)和105.506μg·L~(-1),慢性水质基准分别为0.108μg·L~(-1)、63.797μg·L~(-1)、1.947μg·L~(-1)、2.340μg·L~(-1)和52.753μg·L~(-1);不同类群间生物对重金属的敏感度存在差异,不同重金属对同一类群生物的毒性也存在差异;通过与国内外已有的重金属水质基准值比较,发现水质基准具有明显的区域性,目前基于国外水质基准或我国整体水域特点来制定的太湖水质标准,往往造成对太湖水生生物欠保护或过保护的状况。     

生物质炭对土壤重金属形态转化及其有效性的影响

为了解土壤重金属形态转化及其有效性对生物质炭修复措施的响应,以Cd、Cu、Pb和Zn复合污染水稻土为供试土样,添加不同粒径(1 mm和0.25 mm)和不同施用量(0、1%和5%)的竹炭(BB)、稻草炭(RSB)进行为期1年的恒温((25±1)℃)培养试验后,检测土壤p H、有效磷含量及重金属DTPA有效态含量的变化,并采用BCR连续浸提法分析生物质炭对土壤中重金属元素化学形态再分配的影响.结果表明:稻草炭的施用显著(p0.05)提高了土壤的p H值,且在RSB-5%(0.25 mm)处理下效果最显著;稻草炭的施用显著(p0.05)提高了土壤的有效磷含量,且5%用量比1%用量效果更明显;而竹炭的施用对土壤p H值和有效磷含量均无显著性影响;RSB-5%(0.25 mm)处理对降低土壤中Cd、Cu、Pb和Zn有效态含量的效果最佳,分别减少了34.5%、50.1%、52.5%和52.1%;在细粒径(0.25 mm)稻草炭处理下,酸溶态Cd和Cu向可还原态和可氧化态转化,酸溶态Zn向可还原态转化;在粗粒径(1 mm)竹炭处理下,酸溶态Cu和Zn向可还原态、可氧化态和残渣态转化;酸溶态Pb在稻草炭处理下向可还原态和可氧化态转化,且细粒径比粗粒径效果更佳;竹炭和稻草炭的施用改变了土壤中上述重金属各形态的分配,且5%用量比1%用量效果更明显.     

绿洲边缘新月形沙丘表层沉积物粒度与重金属分布特征

本文以乌兰布和沙漠绿洲边缘工业化城市乌海市下风向典型新月形沙丘为研究对象,分析了新月形沙丘各部位0~10 cm沙物质、沙丘前50 m处大气降尘的粒度及重金属元素变化特征,探讨了重金属物质的来源及其与粒径的相关性,评价了重金属的潜在生态风险.结果表明:沙丘各部位沉积物粒度均以细砂为主,较对照沙丘极细砂含量增高而中砂含量减少.而降尘主要以极细砂、粉粒为主,降尘在沙丘表面的沉降堆积使沙丘表层沙物质细化.沙丘与降尘的重金属含量均为FeMnCrZnCu;Mn、Cu、Zn、Cr含量均高于背景值且发生富集.Mn、Zn含量在空间分布上呈中等变异;Fe、Cu含量在空间分布上为高度变异.Mn、Zn、Cu含量与细颗粒含量呈显著正相关,Zn、Cu含量与中砂含量呈负相关,Fe含量与细砂和中砂含量均呈负相关.Cu、Zn、Cr为人为污染因子,Mn、Fe为自然源因子,但Cr、Mn、Fe又受到自然地质背景和人类活动的共同控制.乌海市下风向新月形沙丘属于低生态风险状态,为轻度污染,需加强废气的治理控制以防重金属污染的进一步加深.     

Cu(II), Fe(III) and Mn(II) combinations as environmental stress factors have distinguishing effects on Enterococcus hirae

Pollution by various heavy metals as environmental stress factors might affect bacteria. It was established that iron (Fe(III)), manganese (Mn(II)) and copper (Cu(II)) ion combinations caused effects on Enterococcus hirae that differed from the sum of the effects when the metals were added separately. It was shown that the Cu²⁺-Fe³⁺ combination decreased the growth and ATPase activity of membrane vesicles of wild-type E. hirae ATCC9790 and atpD mutant (with defective F_oF₁-ATPase) MS116. Addition of Mn²⁺-Fe³⁺ combinations within the same concentration range had no effects on growth compared to control (without heavy metals). ATPase activity was increased in the presence of Mn²⁺-Fe³⁺, while together with 0.2 mmol/L N,N'-dicyclohexylcarbodiimide (DCCD), ATPase activity was decreased compared to control (when only 0.2 mmol/L DCCD was present). These results indicate that heavy metals ion combinations probably affect the FOF1-ATPase, leading to conformational changes. Moreover the action may be direct or be mediated by environment redox potential. The effects observed when Fe³⁺ was added separately disappeared in both cases, which might be a result of competing processes between Fe³⁺ and other heavy metals. These findings are novel and improve the understanding of heavy metals ions effects on bacteria, and could be applied for regulation of stress response patterns in the environment.     

A 1-dodecanethiol-based phase transfer protocol for the highly efficient extraction of noble metal ions from aqueous phase

A 1-dodecanethiol-based phase-transfer protocol is developed for the extraction of noble metal ions from aqueous solution to a hydrocarbon phase, which calls for first mixing the aqueous metal ion solution with an ethanolic solution of 1-dodecanethiol, and then extracting the coordination compounds formed between noble metal ions and 1-dodecanethiol into a non-polar organic solvent. A number of characterization techniques, including inductively coupled plasma atomic emission spectroscopy, Fourier transform infrared spectroscopy, and thermogravimetric analysis demonstrate that this protocol could be applied to extract a wide variety of noble metal ions from water to dichloromethane with an efficiency of >96%, and has high selectivity for the separation of the noble metal ions from other transition metals. It is therefore an attractive alternative for the extraction of noble metals from water, soil, or waste printed circuit boards.     

Cu(II), Fe(III) and Mn(II) combinations as environmental stress factors have distinguishing effects on Enterococcus hirae

Pollution by various heavy metals as environmental stress factors might affect bacteria. It was established that iron (Fe(III)), manganese (Mn(II)) and copper (Cu(II)) ion combinations caused effects on Enterococcus hirae that differed from the sum of the effects when the metals were added separately. It was shown that the Cu^2 +–Fe^3 + combination decreased the growth and ATPase activity of membrane vesicles of wild-type E. hirae ATCC9790 and atpD mutant (with defective F_oF₁-ATPase) MS116. Addition of Mn^2 +–Fe^3 + combinations within the same concentration range had no effects on growth compared to control (without heavy metals). ATPase activity was increased in the presence of Mn^2 +–Fe^3 +, while together with 0.2 mmol/L N,N′-dicyclohexylcarbodiimide (DCCD), ATPase activity was decreased compared to control (when only 0.2 mmol/L DCCD was present). These results indicate that heavy metals ion combinations probably affect the F_OF₁-ATPase, leading to conformational changes. Moreover the action may be direct or be mediated by environment redox potential. The effects observed when Fe^3 + was added separately disappeared in both cases, which might be a result of competing processes between Fe^3 + and other heavy metals. These findings are novel and improve the understanding of heavy metals ions effects on bacteria, and could be applied for regulation of stress response patterns in the environment.     

Composition and source apportionment of dust fall around a natural lake

The aim of this study was to determine the source apportionment of dust fall around Lake Chini, Malaysia. Samples were collected monthly between December 2012 and March2013 at seven sampling stations located around Lake Chini. The samples were filtered to separate the dissolved and undissolved solids. The ionic compositions(NO-3, SO2-4, Cl-and NH+4) were determined using ion chromatography(IC) while major elements(K, Na, Ca and Mg) and trace metals(Zn, Fe, Al, Ni, Mn, Cr, Pb and Cd) were determined using inductively coupled plasma mass spectrometry(ICP-MS). The results showed that the average concentration of total solids around Lake Chini was 93.49 ± 16.16 mg/(m2·day). SO2-4, Na and Zn dominated the dissolved portion of the dust fall. The enrichment factors(EF) revealed that the source of the trace metals and major elements in the rain water was anthropogenic, except for Fe. Hierarchical agglomerative cluster analysis(HACA) classified the seven monitoring stations and 16 variables into five groups and three groups respectively. A coupled receptor model, principal component analysis multiple linear regression(PCA-MLR), revealed that the sources of dust fall in Lake Chini were dominated by agricultural and biomass burning(42%),followed by the earth's crust(28%), sea spray(16%) and a mixture of soil dust and vehicle emissions(14%).     

Cu(Ⅱ), Fe(Ⅲ) and Mn(Ⅱ) combinations as environmental stress factors have distinguishing effects on Enterococcus hirae

Pollution by various heavy metals as environmental stress factors might affect bacteria. It was established that iron(Fe(Ⅲ)), manganese(Mn(Ⅱ)) and copper(Cu(Ⅱ)) ion combinations caused effects on Enterococcus hirae that differed from the sum of the effects when the metals were added separately. It was shown that the Cu2+–Fe3+combination decreased the growth and ATPase activity of membrane vesicles of wild-type E. hirae ATCC9790 and atp D mutant(with defective FoF1-ATPase) MS116. Addition of Mn2+–Fe3+combinations within the same concentration range had no effects on growth compared to control(without heavy metals). ATPase activity was increased in the presence of Mn2+–Fe3+, while together with0.2 mmol/L N,N′-dicyclohexylcarbodiimide(DCCD), ATPase activity was decreased compared to control(when only 0.2 mmol/L DCCD was present). These results indicate that heavy metals ion combinations probably affect the FOF1-ATPase, leading to conformational changes. Moreover the action may be direct or be mediated by environment redox potential.The effects observed when Fe3+was added separately disappeared in both cases, which might be a result of competing processes between Fe3+and other heavy metals. These findings are novel and improve the understanding of heavy metals ions effects on bacteria,and could be applied for regulation of stress response patterns in the environment.