3株常见细菌胞外氨基酸对方解石表面性质的影响

文章以土壤-空气-人体中3株常见细菌为研究对象,采用反相高效液相色谱(RP-HPLC)对3株细菌胞外氨基酸主要组分进行定性定量分析,在此基础上,考察了常见细菌胞外氨基酸对大气可吸入矿物细颗粒-方解石表面性质的影响。结果表明:3株细菌主要氨基酸组分为组氨酸、精氨酸、酪氨酸和胱氨酸;4种氨基酸对方解石都有不同程度的溶蚀作用,影响程度取决于氨基酸的功能、分子结构和添加量。3株常见细菌对方解石作用效果为金黄色葡萄球菌大肠杆菌硅酸盐细菌,由此推断方解石细颗粒物从土壤迁移到空气,再迁移到人体,毒性依次减弱,为建立可吸入矿物细颗粒环境和健康影响评价体系具有重要意义。     

Activated carbon enhanced ozonation of oxalate attributed to HO. oxidation in bulk solution and surface oxidation： Effect of activated carbon dosage and pH

Ozonation of oxalate in aqueous phase was performed with a commercial activated carbon（AC）in this work. The effect of AC dosage and solution pH on the contribution of hydroxyl radicals（HOU） in bulk solution and oxidation on the AC surface to the removal of oxalate was studied. We found that the removal of oxalate was reduced by tert-butyl alcohol（tBA） with low dosages of AC,while it was hardly affected by tBA when the AC dosage was greater than 0.3 g/L. tBA also inhibited ozone decomposition when the AC dosage was no more than 0.05 g/L, but it did not work when the AC dosage was no less than 0.1 g/L. These observations indicate that HOUin bulk solution and oxidation on the AC surface both contribute to the removal of oxalate. HOU oxidation in bulk solution is significant when the dosage of AC is low, whereas surface oxidation is dominant when the dosage of AC is high. The oxalate removal decreased with increasing pH of the solution with an AC dosage of 0.5 g/L. The degradation of oxalate occurs mainly through surface oxidation in acid and neutral solution, but through HOUoxidation in basic bulk solution. A mechanism involving both HOUoxidation in bulk solution and surface oxidation was proposed for AC enhanced ozonation of oxalate.     

表面活性剂提高滤塔净化氯苯废气性能的研究

通过吐温80(Tween80)、十二烷基磺酸钠(SDS)、十六烷基三甲基溴化铵(CTMAB)3种表面活性剂对恶臭假单胞菌P.putida的微生物静态培养结果表明,CTMAB对P.putida有显著抑制作用,SDS和Tween80在低浓度下对细菌的抑制较小,而当浓度在50 mg/L以上时,对细菌的抑制作用较为明显。在对表面活性剂筛选和确定最优添加浓度后,实验以活性炭纤维(activated carbon on fiber,ACOF)作为生物滴滤塔的填料,将Tween80、SDS加入喷淋液中,研究其对滴滤塔处理氯苯废气效果的影响。结果表明,未添加表面活性剂时滴滤塔需要7 d的启动时间,添加后大约需要4 d就可以看到明显的去除效果;而与SDS相比,添加Tween80能够使滤塔在相同时期内去除效果提高10%。在控制滴滤塔气体停留时间为109 s,氯苯气体入口浓度为3 000~5 000 mg/m3,体积负荷为145 g/(m3·h)时,未加表面活性剂的情况下,滴滤塔去除能力为120 g/(m3·h);添加后,SDS可使滴滤塔的去除能力升高到132 g/(m3·h),Tween80可将其提高到140 g/(m3·h)。     

改性蓖麻油酸的制备及其破乳性能研究

以天然有机物蓖麻油酸为原料,分别以正丁醇、乙二醇、丙三醇和季戊四醇为改性剂,经酯化、磺化反应制备了一系列改性蓖麻油酸磺酸盐(分别记为M1,M2,M3和M4),并采用红外光谱验证了其结构。HLB值和表界面张力的测定结果表明:M1~M4的HLB值在13.1~14.9,且依次降低;CMC值均在400 mg/L左右,且降低油水界面张力的能力依次增强。另外,破乳评价结果表明,M1~M4对含水率为45%~65%的W/O乳状液有较好的破乳效果,且随着产物支链化程度的增加,破乳效果依次增强;破乳效果最好的是M4,400 mg/L、80℃下,针对含水率为65%的乳状液2 h时其脱水率为97.44%。     

非一阴离子表面活性剂对PAHs的增溶作用及无机盐的强化效果研究

文章研究了几种非离子和阴离子表面活性剂在单一或混合条件下对多环芳烃（PAHs）萘和菲的增溶作用,并分析了无机盐对表面活性剂增溶PAHs的强化效果.结果表明,在相同浓度条件下,非离子表面活性剂对菲和萘的增溶效果均高于阴离子表面活性剂,其增溶能力大小顺序为：Tween 80 ＞TX-100＞ Tween 20＞ SDS＞SDBS.将非离子与阴离子表面活性剂混合后,对萘和菲的增溶作用大于单一阴离子表面活性剂而小于单一非离子表面活性剂,且增溶效果随着非离子表面活性剂比例的增加而增大.低浓度（0.03 mol/L）的NaCl和Na2SO4可大幅度促进表面活性剂对萘和菲的增溶效果,但随着无机盐浓度的提高,对增溶效果的促进作用不明显.     

新型螯合型表面活性剂增溶菲的热力学和动力学研究

采用批平衡试验法,研究了新型螯合型表面活性剂N-十二酰基乙二胺三乙酸钠(N-LED3A)增溶菲的性能,并探讨了其增溶热力学和动力学特征.结果表明:N-LED3A可有效增溶菲,菲的表观溶解度S*w及其在表面活性剂单体和胶束相的分配系数Kmn和Kmc均随温度升高而增大;N-LED3A的临界胶束浓度(CMC)随温度的升高(15、25、35、45℃)呈现先减小后增大的趋势;菲在N-LED3A单体/水、胶束/水的表观摩尔分配焓变ΔH*mm、ΔH*mc分别为18.30、13.12 kJ·mol-1,菲在水、N-LED3A单体和胶束中的表观摩尔溶解热分别为18.87、37.17和31.99 kJ·mol-1,均为吸热过程,故温度升高有利于菲在N-LED3A单体和胶束中的分配作用,菲在水、N-LED3A单体和胶束中的溶解量随温度升高而增大。动力学方程拟合结果表明,一级动力学方程最适合描述N-LED3A对菲的增溶过程.     

表面活性剂对以污泥为铝源制得的纳米Al（OH）3性质的影响研究

以污泥碳(SC)中回收的铝酸钠为铝源,在制备Al(OH)3的过程中加入表面活性剂PEG-1000(比例在0.01%~0.6%变化),考察其对Al(OH)3表面形貌和结构的影响.研究发现,当加入PEG-1000比例较小时,其空间位阻作用抑制了粒子之间的键合作用,使得Al(OH)3的沉淀效率较高、粒子尺寸较小,也能有效地阻止颗粒的团聚,SBET可以达到340 m2·g-1以上.当PEG-1000加入比例较大时,Al3+的沉淀效率逐渐降低,所得Al(OH)3粒子的尺寸变大,Al(OH)3的SBET和孔体积逐渐变小,平均孔径变大;原因是增多的PEG-1000分子会被包进Al(OH)3的结构中,限制了PEG-1000的表面交联和吸附,使空间位阻效应变差.—CH2—振动峰的出现说明PEG-1000是通过形成化学键的方式连接在Al(OH)3的表面基团上.PEG-1000的使用对于以污泥为铝源制备分散性好、尺寸较小和SBET较大的非晶态Al(OH)3具有重要作用.     

Enhancing plant-microbe associated bioremediation of phenanthrene and pyrene contaminated soil by SDBS-Tween 80 mixed surfactants

The use of surfactants to enhance plant-microbe associated dissipation in soils contaminated with polycyclic aromatic hydrocarbons(PAHs) is a promising bioremediation technology. This comparative study was conducted on the effects of plant-microbe treatment on the removal of phenanthrene and pyrene from contaminated soil, in the presence of low concentration single anionic, nonionic and anionic-nonionic mixed surfactants. Sodium dodecyl benzene sulfonate(SDBS) and Tween 80 were chosen as representative anionic and nonionic surfactants, respectively. We found that mixed surfactants with concentrations less than 150 mg/kg were more effective in promoting plant-microbe associated bioremediation than the same amount of single surfactants. Only about(m/m) of mixed surfactants was needed to remove the same amount of phenanthrene and pyrene from either the planted or unplanted soils, when compared to Tween 80. Mixed surfactants( 150 mg/kg) better enhanced the degradation efficiency of phenanthrene and pyrene via microbe or plant-microbe routes in the soils. In the concentration range of 60–150 mg/kg, both ryegrass roots and shoots could accumulate 2–3 times the phenanthrene and pyrene with mixed surfactants than with Tween 80. These results may be explained by the lower sorption loss and reduced interfacial tension of mixed surfactants relative to Tween 80, which enhanced the bioavailability of PAHs in soil and the microbial degradation efficiency. The higher remediation efficiency of low dosage SDBS-Tween 80 mixed surfactants thus advanced the technology of surfactant-enhanced plant-microbe associated bioremediation.     

Removal of arsenate with hydrous ferric oxide coprecipitation：Effect of humic acid

Insights from the adverse effect of humic acid(HA) on arsenate removal with hydrous ferric oxide(HFO) coprecipitation can further our understanding of the fate of As(V) in water treatment process. The motivation of our study is to explore the competitive adsorption mechanisms of humic acid and As(V) on HFO on the molecular scale. Multiple complementary techniques were used including macroscopic adsorption experiments, surface enhanced Raman scattering(SERS), extended X-ray absorption fine structure(EXAFS) spectroscopy, flow-cell attenuated total reflectance Fourier transform infrared(ATR-FTIR) measurement, and charge distribution multisite complexation(CDMUSIC) modeling. The As(V) removal efficiency was reduced from over 95% to about 10% with the increasing HA concentration to 25 times of As(V) mass concentration. The SERS analysis excluded the HA-As(V) complex formation. The EXAFS results indicate that As(V) formed bidentate binuclear surface complexes in the presence of HA as evidenced by an As-Fe distance of 3.26–3.31 ?. The in situ ATR-FTIR measurements show that As(V) replaces surface hydroxyl groups and forms innersphere complex. High concentrations of HA may physically block the surface sites and inhibit the As(V) access. The adsorption of As(V) and HA decreased the point of zero charge of HFO from 7.8 to 5.8 and 6.3, respectively. The CD-MUSIC model described the zeta potential curves and adsorption edges of As(V) and HA reasonably well.     

Photocatalytic removal of NO and NO2 using titania nanotubes synthesized by hydrothermal method

In this study, the photocatalysts of titania nanotubes(TNTs) were synthesized at different calcination temperatures using commercial Degussa TiO2(P25) as a precursor. The materials were then characterized by BET, SEM, TEM, and XRD analyses. The photocatalytic reactions with NO and NO2 under UV-A irradiation were both performed. The results showed that the photocatalytic reaction rate of NO was much faster than that of NO2, and the conversion of NO2 to nitrate was the rate-limiting step for photocatalytic removal of NOx if the nitrate produced cannot be removed continuously from the photocatalyst surface. For TNTs calcined at different temperatures, a significant enhancement was observed on the total NOx removal efficiency by TNT calcined at 500°C for both NO and NO2 photocatalytic reaction, which could be attributed to its high anatase crystallinity as well as high surface area. These two factors affect primarily on the NO2conversion step in which the high anatase crystallinity could be responsible for the high efficiency at the beginning, while the high surface area could be accounted for retaining this high efficiency from nitric acid poisoning during the test period.