净化SO2的生物膜填料塔中微生物类群分析

对净化废气中SO2的生物膜填料塔内的微生物进行了分离纯化并做鉴定,得到一株嗜酸性氧化硫硫杆菌（Acidithiobacillus thiooxidans IEL001）和一株分类地位非常接近链二孢属（Bispora sp.）的极端嗜酸真菌IEL002,生物膜填料塔内的极端酸性环境和有机营养的缺乏导致生物膜上的微生物种类较为单一,多样性程度不高。本研究还发现IEL002自身并不能氧化单质硫,但它能促进Acidithiobacillus thiooxidans IEL001对单质硫的氧化。     

石墨烯是促进还是抑制嗜酸性氧化亚铁硫杆菌生长?

尽管石墨烯以其独特的光学、电学、力学特性在各大领域都具有广阔的应用前景,但其工业化使用后在环境当中的行为,特别是遗留下的石墨烯对生态系统的毒性研究则鲜见报道.因此,本文以嗜酸性氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans)为目标微生物,探讨不同浓度(1、10、50 mg·L-1)石墨烯对Acidithiobacillus ferrooxidans的毒性效应.结果表明,石墨烯对Acidithiobacillus ferrooxidans的生长有明显抑制作用,且抑制作用随着石墨烯浓度的降低而增强.在石墨烯投加量为1 mg·L-1时,培养48 h后菌株的生长量OD420达到最大值0.045,低于空白组的0.163;并且其可溶性蛋白含量也达到最大值1.546 mg·L-1,低于空白组的3.789 mg·L-1.不同浓度石墨烯对体系p H和ORP均存在不同程度的影响,低浓度下的石墨烯影响最为显著.此外,通过扫描电镜(SEM)和荧光显微镜分析,进一步证实Acidithiobacillus ferrooxidans能在高浓度的石墨烯上生长,而低浓度的石墨烯则会对细胞膜造成损伤,它极其尖锐的边缘是细菌失活的有效机制.因此,石墨烯的毒性具有剂量效应,这一结果可为石墨烯合理利用及评价其生态毒性提供理论依据.     

Effect of sediment size on bioleaching of heavy metals from contaminated sediments of Izmir Inner Bay

The effect of sediment size on metals bioleaching from bay sediments was investigated by using fine (< 45 μm), medium (45-300 μm), and coarse (300-2000 μm) size fractions of a sediment sample contaminated with Cr, Cu, Pb, and Zn. Chemical speciation of the metals in bulk and size fractions of sediment were studied before and after bioleaching. Microbial activity was provided with mixed cultures of Acidithiobacillus thiooxidans and Acidithiobacillus ferrooxidans. The bioleaching process was carried out in flask experiments for 48 days, by using 5% (W/V) of solid concentration in suspension. Bioleaching was found to be efficient for the removal of selected heavy metals from every size fraction of sediments, where the experiments with the smaller particles resulted in the highest solubilization ratios. At the end of the experimental period, Cr, Cu, Pb and Zn were solubilized to the ratios of 68%, 88%, 72%, and 91% from the fine sediment, respectively. Higher removal efficiencies can be explained by the larger surface area provided by the smaller particles. The changes in the chemical forms of metals were determined and most of the metal releases were observed from the reducible and organic fractions independent from grain size. Higher concentrations were monitored in the residual fraction after bioleaching period, suggesting they are trapped in this fraction, and cannot be solubilized under natural conditions.     

微生物法烟气脱硫技术研究

采用微生物（氧化亚铁硫杆菌，简称TF菌）法脱除烟气中的二氧化硫。在相同操作条件下，比较了传统的工业化 方法稀硫酸吸收法（千代田法）与本法的优劣，研究了液气化、二氧化硫浓度、三价铁离子浓度等因素对吸收效率的影响；分析了脱硫反应前后吸收率pH值、三价铁离子浓度的变化。研究结果表明：适宜的液气比（12.5L/Nm^3 以上）、二氧化硫浓度（1000－5000ppm)和三价铁离子浓度（0.6g/L以上）能使该法具有较高（＞98％）的脱硫率。在常温常压操作条件下，微生物法的脱硫率远优于千代田法，具有一定的工业化价值。     

Isolation, identification and arsenic-resistance of Acidithiobacillus ferrooxidans HX3 producing schwertmannite

Schwertmannite, a ubiquitous mineral present in iron oxyhydroxides formed in iron- and sulfate-rich acid media, favors incorporation of some toxic anions in its structure. We reported an iron-oxidizing bacterial strain HX3 from a municipal sludge that facilitates the formation of pure schwertmannite in cultures. Ferrous iron oxidation by the isolated strain HX3 was optimum at an initial pH of 2.0-3.3 and temperature of 28-35°C. Pure schwertmannite was found through bacterial oxidation of ferrous iron at an initial pH 2.8and temperature 28°C. Following 16 S rDNA gene sequence analysis the bacterial strain HX3 was identified as Acidithiobacillus ferrooxidans. The arsenic-resistance A. ferrooxidans HX3 showed the potential of environmental application in arsenic removal from the As（Ⅲ）- and iron-rich acid sulfate waters directly by As（Ⅲ） adsorption or the formation of schwertmannite in the environment.     

软锰矿与氧化亚铁硫杆菌吸收SO2过程中的影响因素

研究了低浓度软锰矿浆与氧化亚铁硫杆菌(Thiobacillus ferrooxidans,简称 T.f)联合吸收SO2过程中软锰矿浆浓度、T.f菌液量、O2体积分数、气体流量以及SO2进口浓度对硫酸根生成的影响.研究表明:在该体系中,生成的硫酸根浓度随着软锰矿浆浓度、T.f菌液量、O2体积分数以及气体流量的增加而增大;随着进口SO2浓度的增加,硫酸根的生成呈现先增加后减少的趋势.     

多批次生物沥浸对猪粪重金属脱除及养分和脱水性的影响

猪粪重金属脱除及脱水性提升对其资源化利用具有重要意义.本研究以氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans,A.f)作为生物沥浸微生物,探究了多批次生物沥浸对猪粪重金属脱除及养分和脱水性的影响.研究表明,当A.f菌液与原始猪粪(含固率为3.5％)体积比为1∶1时,生物沥浸进程缓慢,而将猪...     

不同污泥浓度对生物沥滤过程的影响

以硫酸亚铁盐作为底物,氧化亚铁硫杆菌（Thiobacillus ferrooxidans）为主要沥滤微生物,在底物投配比为10 g/L,温度为25℃,曝气量为1 L/min的条件下,对5种不同浓度的桂林城市污泥中重金属进行生物沥滤试验。结果表明,生物沥滤的污泥浓度宜控制在25.6 g/L,沥滤3 d后,污泥中超标元素Cu、Zn和Cd的去除率分别达到58.17%、75.90%和93.64%,沥滤处理后污泥中残余重金属含量符合污泥农用的国家标准。     

酵母菌与两种硫杆菌复合对污泥中三价铬的去除

研究了氧化亚铁硫杆菌LX5(Thiobacillus ferrooxidans LX5)、氧化硫硫杆菌TS6(Thiobacillus thiooxidans TS6)和耐酸性酵母菌R30(Rhodotorula sp.R30)对重金属铬(Cr³⁺)的耐受性.结果表明,700mg/L的Cr³⁺对硫杆菌LX5、TS6的生长和氧化活性影响不大,但Cr³⁺浓度大于500mg/L时明显抑制酵母菌R30的生长.酵母菌R30与硫杆菌LX5和TS6复合能明显加速污泥淋滤的进程,最佳复合比为酵母菌R30接种量2.0%,硫杆菌LX5和TS6接种量10%.分别用含酵母菌R30数量为10⁴个/mL和102个/mL的酸化污泥作接种物进行污泥淋滤,发现淋滤过程中pH值下降的速度没有明显差异,而在淋滤起始时添加2.0%的酵母菌R30,则淋滤反应提前36h结束.由此可见,在其它条件相同的污泥淋滤中,污泥中所含耐酸性酵母菌的数量是加快淋滤的关键.     

The effects of <Emphasis Type="Italic">Acidithiobacillus ferrooxidans</Emphasis> on the leaching of cobalt and strontium adsorbed onto soil particles

Bioleaching from soil artificially contaminated with analogues of radionuclides, Co and Sr, was carried out using a Fe-oxidizing bacterium, Acidithiobacillus ferrooxidans. Due to bacterial metabolism, the pH and dissolved Fe³⁺ concentration in a biotic slurry decreased and increased respectively, over time, but the concentrations of Co and Sr extracted from the soil showed no significant enhancement compared with those under abiotic control. In both cases, Co and Sr were leached from the soil during the initial period of the experiment, due to the initially low solution pH of 2.0, and the dissolved concentrations remained almost constant for the duration of the experiment (300 h). Since oxidation of Fe²⁺ by A. ferrooxidans led to the production of Fe precipitates and colloidal suspensions, the Co and Sr extracted into solution were most likely re-adsorbed onto the Fe solids. Also, A. ferrooxidans, without an external supply of Fe²⁺, extracted almost equal or greater amounts of Co and Sr from the soil than when Fe²⁺ was supplied. Under the same leaching conditions, the extent of Sr removal was much lower than that of Co. On the contrary to the high efficiency of microbial metal leaching in biohydrometallurgy for low-graded sulfide ores, which has been widely documented, conventional bioleaching techniques with A. ferrooxidans supplied with enough Fe²⁺ showed low efficiency for the removal of radionuclides loosely bound onto soil particle surfaces.