Surfactant complexation may have significant effects on the environmental behavior of nano-particles.In order to understand the ecological exposure of nano-materials,it is important to determine the stability and mobility of surfactant-complexed nano-materials in aqueous systems.In this study,the aggregation and transport of C_(60) complexed by the surfactant sodium dodecyl benzene sulfonate(SDBS)were investigated.It was found that SDBS-complexed C-_(60) had aζ-potential of-49.5 m V under near-neutral p H conditions and remained stable during an aging period of 15 days.It had a critical coagulation concentration of 550 mmol/L for Na Cl,which was higher than common natural colloids and many kinds of raw nano-materials,and was comparable to those of many kinds of surface-modified nano-materials.SDBS enhanced the stability of C_(60) colloid;however,at the same time,it also enhanced the colloidal particle aggregation rate.Much higher mobility was found for SDBS-complexed C_(60) than C_(60) colloid.Increase in ionic strength,Ca~(2+) concentration or Al~(3+) concentration decreased the mobility.In general,SDBS-complexed C_(60) had high stability and mobility. 相似文献
Long-term use of chlorpyrifos poses a potential threat to the environment that cannot be ignored, yet little is known about the succession of substrate microbial communities in constructed wetlands(CWs) under chlorpyrifos stress. Six pilot-scale CW systems receiving artificial wastewater containing 1 mg/L chlorpyrifos were established to investigate the effects of chlorpyrifos and wetland vegetation on the microbial metabolism pattern of carbon sources and community structure, using BIOLOG and denaturing gradient gel electrophoresis(DGGE) approaches. Based on our samples, BIOLOG showed that Shannon diversity(HV) and richness(S) values distinctly increased after 30 days when chlorpyrifos was added. At the same time, differences between the vegetated and the non-vegetated systems disappeared. DGGE profiles indicated that H Vand S had no significant differences among four different treatments. The effect of chlorpyrifos on the microbial community was mainly reflected at the physiological level. Principal component analysis(PCA) of both BIOLOG and DGGE showed that added chlorpyrifos made a difference on test results.Meanwhile, there was no difference between the vegetation and no-vegetation treatments after addition of chlorpyrifos at the physiological level. Moreover, the vegetation had no significant effect on the microbial community at the genetic level. Comparisons were made between bacteria in this experiment and other known chlorpyrifos-degrading bacteria. The potential chlorpyrifos-degrading ability of bacteria in situ may be considerable. 相似文献
为了研究污泥在低温低湿条件下的干燥规律,获得表征水分迁移过程的有效水分扩散系数(D_(eff))和活化能(E_a),以脱水污泥为研究对象进行了污泥低温低湿干燥试验,探讨了温度(30℃、35℃、40℃、45℃、50℃)和相对湿度(20%、40%、60%)对污泥水分比(MR)和干燥速率(DR)的影响。结果表明,污泥的低温低湿干燥过程属于内部迁移控制,即水分扩散速率决定干燥速率。根据试验数据建立了污泥水分迁移动力学模型,并与6种常用薄层干燥模型进行拟合,通过对决定系数(R~2)、方差(χ~2)和残差平方和(RSS)的比较,得出污泥低温低湿干燥过程可以用Page模型来描述。结合Fick第二定律,得到不同温度(30~50℃)、湿度(20%~60%)条件下污泥有效水分扩散系数的范围为(0.699~1.991)×10~(-9)m~2/s;对传统的Arrhenius公式进行湿度修正,获得了干燥介质温度和湿度对污泥干燥特性影响的数学模型及活化能E_a=23.83 k J/mol。 相似文献
With the increasing of high saline waste sludge production, the treatment and utilization of saline waste sludge attracted more and more attention. In this study, the biological hydrogen production from saline waste sludge after heating pretreatment was studied. The substrate metabolism process at different salinity condition was analyzed by the changes of soluble chemical oxygen demand (SCOD), carbohydrate and protein in extracellular polymeric substances (EPS), and dissolved organic matters (DOM). The excitation-emission matrix (EEM) with fluorescence regional integration (FRI) was also used to investigate the effect of salinity on EPS and DOM composition during hydrogen fermentation. The highest hydrogen yield of 23.6 mL H2/g VSS and hydrogen content of 77.6% were obtained at 0.0% salinity condition. The salinity could influence the hydrogen production and substrate metabolism of waste sludge.