菌株Dyella ginsengisoli LA-4吸附Ni~(2+)的条件优化及特性研究

主要考察了菌株Dyella ginsengisoli LA-4对重金属Ni2+的吸附性能,同时,利用表面响应法对菌株Dyella ginsengisoli LA-4吸附Ni2+的条件(接种量、pH、Ni2+浓度等)进行了优化,并考察了其动力学及吸附等温曲线特性.实验结果表明,菌株Dyella ginsengisoli LA-4吸附Ni2+的最优条件为:接种量10.64 g.L-1,pH为6.50,Ni2+浓度为19.20 mg.L-1,此时的Ni2+最大去除率为99%.动力学分析表明,吸附平衡时间约为30 min,吸附可分为表面快速吸附和缓慢重金属积累两个阶段.利用Langmuir吸附模型能较好地描述菌株Dyella ginsengisoli LA-4对Ni2+的等温吸附行为,最大吸附量为25.81 mg.g-1.     

Adsorption removal of phosphate from aqueous solution by active red mud

Red mud is the waste of alumina industry and has high TiO_2 and Fe_2O_3 content which are active components for the adsorption of anion pollutants.In this study,the uptake of phosphate by red mud activated by heat treatment and acid-heat treatment was investigated. The factors influencing the adsorption were also investigated.The result showed that the red mud sample treated using acid-heat method at 80℃with 0.25 mol/L HC1 for 2 h achieved the highest phosphate removal.For the heat-activated red mud,the sample heated at 700℃for 2 h preformed better than the other heat treatment.Phosphate removal by the activated red mud was significantly pH dependent,and pH 7 was the optimal pH for phosphate removal.The adsorption fits Langmuir isotherm model well and the maximum adsorption capacities of the acid-heat activated red mud and the heat activated samples were 202.9 mgP/g and 155.2 mgP/g,respectively.     

Nitrous oxide gas removal by using compost-based biofilter medium

This paper is aimed at introducing our research result in the efficiency in removing nitrous oxide gas (N2O) by using compost as a medium filter,which is actually a kind of manure derived from cow faeces at Kukusan Kelurahan farm containg wood chips and some other microorganisms.Practically speaking,N2O is a major greenhouse gas,whose continuous presence in the atmosphere is expected to last over a 100 years and produce its radiative warming effect just next to CO2.In spite of its rather small concentration in the atmosphere,it is the Number Four largest greenhouse gas contributor to the overall global warming,behind carbon dioxide,methane and water vapour.The biofiltration experiments we have conducted to explore its removing rate of N2O from flue gas help us to find various operating factors in the biofilter system.So far as we know,N2O gas has been fed from the top of the column.It was flowing through the column when it is made to get circulated with a peristaltic pump for 6 hours.The data obtained in our paper prove to be in conformity with the Langmuir adsorption model.The highest N2O gas removing efficiency can be made to be as high as 70.22% at the highest biofilter length of 50 cm with the gas flowing rate of 200 mL/min.The results of this research have finally been modeled by the Langmuir adsorption isotherm formula with its K value obtained being 16.949 L/mol.