排序方式: 共有5条查询结果,搜索用时 9 毫秒
1
1.
The preparation of immobilizing-catalysts for decomposing ozone by using dipping method was studied. XRD, XPS and TEM were used to characterize the catalysts. The three kinds of catalysts were selected preferentially, and their catalytic activities were investigated. The results showed that the catalyst with activated carbon dipping acetate( active components are Mn:Cu = 3:2, active component proportion in catalyst is 15%, calcination temperature is 200℃ ) has the best catalytic activity for ozone decomposing. One gram of catalyst can decompose 17.6g ozone at initial ozone concentration of 2.5g/m^3 and the residence time in reactor of 0.1s. The experimental results also indicated that humidity of reaction system had negative effect on catalytic activity. 相似文献
2.
通过静态实验,考察了电子供体类型及用量对厌氧条件下微生物去除地下水中高氯酸盐的影响.结果表明,电子供体醋酸盐和H2的加入,可以明显提高ClO4-的去除率,驯化后的微生物去除ClO4-的速率比未加入电子供体时提高约1.4~3倍.Monod动态模型能很好地拟合两种电子供体环境下ClO4-的微生物去除过程,分别以醋酸盐和H2作为电子供体时,基质半饱和常数Ks为12.6 mg·L-1和2.2 mg·L-1,最大比基质消耗速率Vm为0.45 d-1和0.08 d-1.动力学参数表明,本实验条件下,异养型混合菌去除ClO4-的效果明显优于自养型混合菌;在少数受高浓度ClO4-污染的地下水环境中,为了提高ClO4-的去除速率只有通过增加菌体浓度或提高微生物酶的活性来实现.随着电子供体醋酸盐用量增加,ClO4-的(比)消耗速率逐渐增大.当初始CH3COO-与ClO4-的比例为3.80 mg(COD)/mg(ClO4-)时,比消耗速率v最大(0.27 d-1). 相似文献
3.
4.
5.
了解特定环境中高氯酸盐(ClO-4)降解菌的群落组成,对ClO-4的降解具有重要的指导意义。通过添加醋酸盐作为电子供体降解ClO-4,利用高通量测序(HiSeq 2000)的方法获得了复杂环境中生物群落的组成,对比了降解前后菌种结构的变化。结果表明,补充醋酸盐的降解体系(Acetate Degradation,AD)将10 mg/L ClO-4降至检出限以下需100 h。降解完毕后代表性的ClO-4降解菌Dechloromonas的相对丰度为0.2%,与原始活性污泥相比无明显差别;另一典型ClO-4降解菌脱氯菌属Azospira相对丰度为3.2%;一些同时参与ClO-4降解和脱氮作用的细菌如假单胞菌属Pseudomonas也有检出,相对丰度为8%。异养条件下ClO-4降解是假单胞菌属Pseudomonas和脱氯菌属Azospira起主导作用。AD体系内菌种多样性小于原始活性污泥。电子供体的加入使活性污泥类的混合体系内生物群落结构单一化,使降解基质具备了在特定环境下针对某种污染物降解的能力。 相似文献
1