Mobilization of arsenic from contaminated sediment by anionic and nonionic surfactants

The increasing manufacture of surfactants and their wide application in industry,agriculture and household detergents have resulted in large amounts of surfactant residuals being discharged into water and distributed into sediment. Surfactants have the potential to enhance arsenic mobility, leading to risks to the environment and even human beings. In this study, batch and column experiments were conducted to investigate arsenic mobilization from contaminated sediment by the commercial anionic surfactants sodium dodecylbenzenesulfonate(SDBS), sodium dodecyl sulfate(SDS), sodium laureth sulfate(AES)and nonionic surfactants phenyl-polyethylene glycol(Triton X-100) and polyethylene glycol sorbitan monooleate(Tween-80). The ability of surfactants to mobilize arsenic followed the order AES SDBS SDS ≈ Triton X-100 Tween 80. Arsenic mobilization by AES and Triton X-100 increased greatly with the increase of surfactant concentration and p H, while arsenic release by SDBS, SDS and Tween-80 slightly increased. The divalent ion Ca~(2+) caused greater reduction of arsenic mobilization than Na~+. Sequential extraction experiments showed that the main fraction of arsenic mobilized was the specifically adsorbed fraction. Solid phase extraction showed that arsenate(As(V)) was the main species mobilized by surfactants,accounting for 65.05%–77.68% of the total mobilized arsenic. The mobilization of arsenic was positively correlated with the mobilization of iron species. The main fraction of mobilized arsenic was the dissolved fraction, accounting for 70% of total mobilized arsenic.     

膨润土对复合污染中表面活性剂的吸附及机理

选取阳离子表面活性剂氯化十六烷基吡啶(CPC)、阴离子表面活性剂十二烷基苯磺酸钠(SDBS)及非离子表面活性剂Triton X-100(TX-100)为代表,研究了其在膨润土上的吸附行为,探讨了膨润土阳离子交换容量(CEC)、温度、盐度对CPC吸附的影响.结果表明,Na基膨润土对CPC的吸附性能最好,对SDBS基本无吸附,对TX-100的吸附介于两者之间.Na基膨润土对CPC的吸附是阳离子交换和疏水键缔合共同作用的结果,对TX-100的吸附主要是通过其与膨润土硅氧表面间的氢键作用,同时通过疏水键作用形成吸附双分子层;SDBS在Ca基膨润土上的吸附损失量先增大后减小,在1.5倍临界胶束浓度 (CMC)时达到极大值,主要机理是SDBS与膨润土中的Ca²⁺产生沉淀作用,而胶束具有再溶解沉淀的作用.膨润土对CPC的吸附量随着温度升高而降低,随着CEC的增大而增大,一定浓度NaCl的加入有利于其在膨润土上的吸附.     

阳-非离子混合表面活性剂对沉积物吸附硝基苯的影响

研究了非离子表面活性剂Triton X-100、阳离子表面活性剂氯化十六烷基吡啶(CPC)及其混合物在沉积物上的吸附行为,探讨了它们对沉积物吸附硝基苯的影响.结果表明,CPC和Triton X-100在沉积物上的吸附等温线均为非线性,吸附量随着平衡浓度的增加急剧增加,并迅速达到最大吸附量.低浓度CPC能明显增加Triton X-100在沉积物上的吸附,而高浓度的CPC则显著降低Triton X-100在沉积物上的吸附.Triton X-100略微降低CPC在沉积物上的吸附.在表面活性剂浓度较低的实际环境中,无论是阳离子或非离子表面活性剂,将主要被土壤或沉积物吸附并固定.硝基苯在沉积物上的吸附等温线为线性.CPC和Triton X-100促进沉积物对硝基苯的吸附,CPC-Triton X-100混合表面活性剂溶液能进一步增强沉积物对硝基苯的吸附.因此,阳离子和非离子混合表面活性剂可增强土壤或沉积物对有机污染物的吸附固定能力,也可以用来制备有机膨润土以提高其吸附处理废水的性能.     

Effects of surfactants on graphene oxide nanoparticles transport in saturated porous media

Transport behaviors of graphene oxide nanoparticles (GONPs) in saturated porous media were examined as a function of the presence and concentration of anionic surfactant (SDBS) and non-ionic surfactant (Triton X-100) under different ionic strength (IS). The results showed that the GONPs were retained obviously in the sand columns at both IS of 50 and 200 mmol/L, and they were more mobile at lower IS. The presence and concentration of surfactants could enhance the GONP transport, particularly as observed at higher IS. It was interesting to see that the GONP transport was surfactant type dependent, and SDBS was more effective to facilitate GONP transport than Triton X-100 in our experimental conditions. The advection–dispersion–retention numerical modeling followed this trend and depicted the difference quantitatively. Derjaguin–Landau–Verwey–Overbeek (DLVO) interaction calculations also were performed to interpret these effects, indicating that secondary minimum deposition was critical in this study.     

Adsorption of mixed cationic-nonionic surfactant and its effect on bentonite structure

The adsorption of cationic-nonionic mixed surfactant onto bentonite and its effect on bentonite structure were investigated. The objective was to improve the understanding of surfactant behavior on clay mineral for its possible use in remediation technologies of soil and groundwater contaminated by toxic organic compounds. The cationic surfactant used was hexadecylpyridinium bromide (HDPB), and the nonionic surfactant was Triton X-100 (TX100). Adsorption of TX100 was enhanced significantly by the addition of HDPB, but this enhancement decreased with an increase in the fraction of the cationic surfactant. Part of HDPB was replaced by TX100 which decreased the adsorption of HDPB. However, the total adsorbed amount of the mixed surfactant was still increased substantially, indicating the synergistic effect between the cationic and nonionic surfactants. The surfactant-modified bentonite was characterized by Brunauer-Emmett-Teller specific surface area measurement, Fourier transform infrared spectroscopy, and thermogravimetric-derivative thermogravimetric/differential thermal analyses. Surfactant intercalation was found to decrease the bentonite specific surface area, pore volume, and surface roughness and irregularities, as calculated by nitrogen adsorption-desorption isotherms. The co-adsorption of the cationic and nonionic surfactants increased the ordering conformation of the adsorbed surfactants on bentonite, but decreased the thermal stability of the organobentonite system.     

Sorption and transport studies of cetyl trimethylammonium bromide (CTAB) and Triton X-100 in clayey soil

Surfactants are soil washing agents and facilitators for subsurface remediation of hydrocarbon spills.It is important to understand the sorption and transport behavior of surfactants for enhanced soil remediation.The adsorption and desorption isotherms of cetyl trimethylammonium bromide (CTAB) and Triton X-100 with sand and kaolinite have been quantified.Kaolinite clay had the highest sorption capacity compared to blasting sand.Transport parameters such as diffusion coefficient (D) and retardation factor (R) of the above mentioned surfactant solutions were determined in clayey soils (82.5% sand and 17.5% kaolinite mixture) with near zero and 0.1 g/L ionic strength.NaCl was used as the electrolyte solution.Convection-Diffusion equation was used to model the breakthrough curves of the surfactants.Bromide ion was chosen as the tracer material in order to characterize the column.CTAB and Triton X-100 were used to flush the perchloroethylene (PCE) contaminated soil.The effectiveness of CTAB and Triton X-100 in flushing the PCE from the contaminated soil was quantified.     

A laboratory scale study on arsenic（Ⅴ） removal from aqueous medium using calcined bauxite ore

The present work deals with the As（Ⅴ） removal from an aqueous medium by calcined refractory grade bauxite （CRB） as a function of solution pH, time, As（Ⅴ） concentration and temperature. The residual As（Ⅴ） was lowered from 2 mg/L to below 0.01 mg/L in the optimum pH range 4.0-7.0 using a 5 g/L CRB within 3 h contact time. The adsorption data fits well with Langmuir isotherm and yielded Langmuir monolayer capacity of 1.78 mg As（Ⅴ）/g of CRB at pH 7.0. Presence of anions such as silicate and phosphate decreased As（Ⅴ） adsorption efficiency. An increase temperature resulted a decrease in the amount of As（Ⅴ） adsorbed by 6%. The continuous fixed bed column study showed that at the adsorbent bed depth of 30 cm and residence time of 168 min, the CRB was capable of treating 340 bed volumes of As（V） spiked water （C0 = 2 mg/L） before breakthrough （Ce = 0.01 mg/L）. This solid adsorbent, although not reusable, can be considered for design of adsorption columns as an efficiency arsenic adsorption media.     

北京土壤对甲苯和萘的吸附及影响因素分析

通过静态吸附实验,研究了北京地区土壤对甲苯和萘的吸附行为,考察了温度和表面活性剂对甲苯和萘吸附的影响.结果表明,尽管7种土壤对甲苯和萘的吸附能力差别较大,但其吸附等温线均很好的符合Freundlich吸附模式;同一土壤中,萘的吸附量大于甲苯的吸附量.温度升高不利于甲苯和萘在土壤中的吸附.十六烷基三甲基溴化铵(CTAB)和十二烷基苯磺酸钠(SDBS)均利于甲苯和萘在土壤表面的解吸,CTAB和SDBS对甲苯和萘的解吸率最高分别可达27.5%、12.1%和64.3%、48.8%,说明SDBS的解吸效果更好.甲苯     

表面活性剂对极性有机物在沉积物上吸附的影响

研究了苯酚、苯胺和对硝基苯酚在沉积物-十二烷基苯磺酸钠(SDBS)体系中的分配特性.结果表明200mg/L和1200mg/L的SDBS存在下,苯胺和对硝基苯酚的沉积物-水分配系数均增大,分配作用的增大倍数与有机物的K_ow呈正相关;苯酚的分配系数则因表面活性剂存在浓度的不同分别增大和减小.十二烷基硫酸钠(SDS)、Triton X-100(TX100)和Brij30存在下,苯酚等温吸附实验表明:表面活性剂浓度约低于其临界胶束浓度(CMC)时,苯酚的吸附量增大;表面活性剂浓度约高于其CMC时,苯酚的吸附量比纯水中的吸附量小.     

Evaluation of the adsorption potential of titanium dioxide nanoparticles for arsenic removal

The adsorption potential of titanium dioxide (TiO2) nanoparticles for removing arsenic from drinking water was evaluated. Pure and iron-doped TiO2 particles are synthesized via sol-gel method. The synthesized TiO2 nanoparticles were then immobilized on ordinary sand for adsorption studies. Adsorption isotherms were conducted on the synthesized nanoparticles as well as the sand coated with TiO2 nanoparticles under varying conditions of air and light, namely, the air-sunlight (A-SL), air-light (AL), air-dark (AD) and nitrogen-dark (ND). X-Ray diffraction (XRD) analysis showed that the pure and the iron-doped TiO2 nanoparticles were in 100% anatase crystalline phase with crystal sizes of 108 and 65 nm, respectively.Adsorption of arsenic on the three adsorbents was non-linear that could be described by the Freundlich and Langmuir adsorption models. Iron doping enhanced the adsorption capacity of TiO2 nanoparticle by arresting its grain growth and making it visible light responsive resulting in a higher affinity for arsenic. Similarly, the arsenic removal by adsorption on the sand coated with TiO2 nanoparticles was the highest among the three types of sand used. In all cases, As(V) adsorbed more compared with As(III). Solution pH appeared to be the most important factor in controlling the amount of arsenic adsorbed.     

磁性吸附材料CuFe2O4吸附砷的性能

根据Cu(Ⅱ)和Fe(Ⅲ)都对砷有较强的亲和性,制备了同时含有Cu(Ⅱ)和Fe(Ⅲ)的、可用磁分离方法进行分离回收的磁性吸附材料CuFe₂O₄,并对其进行了表征及吸附砷的性能研究.结果表明,该吸附剂对砷的吸附能力与溶液pH有关,在弱酸性及中性条件下,吸附砷的能力最强,而对As(V)的吸附能力比对As(Ⅲ)更强些,在平衡浓度为10μg/L时,其吸附容量可达10mg/g左右,可以很容易地将水中浓度为1～20mg/L的As(V)降到10μg/L以下.实验考察了几种无机阴离子对吸附砷的影响,表明较高浓度(砷浓度的20倍)的硫酸盐对As(Ⅲ)和As(V)的吸附均有一定影响,盐酸盐及磷酸盐则影响不明显;负载的As(V)可较容易地用0.1mol/L NaOH洗脱下来,使吸附剂再生,而As(Ⅲ)则难以洗脱,这与2种价态砷的吸附机理不同有关.     

生物表面活性剂皂角苷对菲在水和土壤间分配行为影响

文章比较研究了皂角苷(saponin)、Triton X-100以及二者的混合物对多环芳烃菲在土壤和水相间分配行为的影响。结果表明,在所选择的表面活性剂中,皂角苷对菲在水和土壤间的分配具有最强的增溶能力。在竞争吸附的作用下,随着加入的表面活性剂的量不同,菲在水和土壤间的分配行为也有差异。当表面活性剂的浓度较低时,促进菲在土壤上的吸附;当加入的表面活性剂的量超过其临界胶束浓度(CMC)时,菲在水和土壤间的分配系数随着表面活性剂浓度的增大出现持续减小的趋势。并且在相同浓度下,皂角苷和TritonX-100组成的混合表面活性剂的增溶能力比单独使用非离子表面活性剂Triton X-100强。同样在混合表面活性剂的协同增溶作用下,菲在水和土壤间的分配系数随着表面活性剂浓度的增加出现持续减小的趋势。     

表面活性剂对土壤中多氯联苯的洗脱研究

采用实验室配置的PCBs污染土壤,以曲拉通X-100、吐温-80、SDS、SDBS 4种表面活性剂进行洗脱试验研究。结果表明:对于单一表面活性剂,SDS对污染土壤中多氯联苯的洗脱效果最好;采用1:20的固液比,进行2~3次洗脱,洗脱率可达50%以上;洗脱时间对洗脱效果影响不大;SDS—吐温-80混合表面活性剂对多氯联苯有协同增溶作用,且在土壤上的吸附损失较小,SDS和吐温-80的最佳质量比为5:5,在此条件下,浓度为7 000 mg/L的混合表面活性剂对多氯联苯污染土壤进行3次洗脱,洗脱率可高达97.89%。     

五种表面活性剂对柴油污染土壤清洗效果的比较

研究了十二烷基硫酸钠(SDS)、十二烷基苯磺酸钠(SDBS)、皂苷(saponin)、月桂醇聚氧乙烯(23)醚(Brij35)、Triton X-100五种表面活性剂对中度柴油污染土壤的清洗效果,考察柴油和土壤混合后在不同时间段的挥发特点,认为污染时长会直接影响表面活性剂清洗修复的效果,增大清洗剂浓度可以提高对新污染土壤的洗脱率,但对老化污染土壤的效果并不明显;对不同含油量的污染土壤清洗,研究污染程度对洗脱率变化的影响,当达到一定含油量后洗脱效果产生突变。不同表面活性剂在相同CMC倍数下清洗能力存在差异,其顺序为SDS>SDBS>Triton X-100>皂苷>Brij35。     

液固比对土壤洗涤去除多环芳烃效果的影响

液固比是影响土壤洗涤污染物去除率的重要因素.以Triton X-100和Tween-80为洗涤剂,采用洗涤去除率(R)、吸附损失率(Vs)和新定义的指标增溶百分比(SP)分析液固比对土壤洗涤去除目标多环芳烃效果的影响.结果表明,液固比对土壤洗涤去除多环芳烃效果影响显著.R随液固比增加呈非线性形式增大,液固比10∶1后R增长变缓.同一液固比时,洗涤去除率Triton X-100>Tween-80.Vs随液固比增加显著减少,液固比10∶1后逐渐变缓.同一液固比时,吸附损失率Triton X-100相似文献   

表面活性剂对苯并[a]芘在黑炭表面吸附解吸的影响

通过静态吸附实验,研究了3种不同类型的表面活性剂(阳离子∶十六烷基三甲基溴化铵,CTAB;阴离子∶十二烷基苯磺酸钠,SDBS∶非离子,曲拉通100,TX100)对苯并[a]芘(BaP)在黑炭表面吸附解吸的影响.结果表明,3种表面活性剂的存在均会增加BaP在黑炭表面吸附的非线性程度.CTAB的存在可以促进BaP在黑炭表面的吸附同时抑制了BaP的解吸,然而SDBS的存在降低了BaP在黑炭表面的吸附并增加了吸附过程的可逆性.与CTAB和SDBS不同,TX100对BaP在黑炭表面吸附解吸的影响取决于其添加浓度.低浓度的TX100(50 mg.L-1)能够促进BaP在黑炭上的吸附并抑制BaP的解吸,吸附能力参数Kd值(在ce=50μg.L-1下)从188 062 mL.g-1增大到264 179 mL.g-1,解吸滞后指数HI从0.44降低到0.39.随着TX100浓度增加到150 mg.L-1和200 mg.L-1,TX100对BaP的吸附表现出抑制作用并能够促进BaP的解吸,Kd值(在ce=50μg.L-1下)从188 062 mL.g-1分别降低到182 751 mL.g-1和178 730 mL.g-1,解吸滞后指数从0.44分别升高到0.65和0.70.本研究为预测多环芳烃在表面活性剂污染的环境中的分布特征和最终归趋提供了理论依据.     

CTAC改性活性炭去除水中砷(V)的柱实验吸附和再生研究

为了开发一种能有效去除水中砷的吸附材料, 研究了十六烷基三甲基氯化铵(CTAC)改性活性炭后, 活性炭对水中五价砷As(V)的去除效果.研究中利用动态小柱实验(Rapid small-scale column test, RSSCT)探讨了CTAC改性后活性炭对砷的吸附能力、影响吸附能力的因素和活性炭再生方法.结果表明, CTAC改性能有效提高活性炭对As(V)的吸附.活性炭对As(V)的吸附受溶液pH、空床接触时间、进水中砷浓度及水中其他离子存在的影响.另外, 1 mol·L^-1的盐酸能有效对吸附穿透后的活性炭进行再生,再生后的活性炭可以重复使用.同时,柱实验中对出水CTAC的检测结果表明, CTAC和活性炭的结合非常稳定.     

Removal of trace arsenic（V） and phosphate from water by a highly selective ligand exchange adsorbent

The ligand exchange adsorbent could be used to remove the toxic arsenic(V) and phosphate efficiently from water even in the presence of foreign anions and possible to apply in chemical industry.     

表面活性剂增溶洗脱土壤中多环芳烃的效果研究

表面活性剂增效洗脱修复技术被广泛应用于土壤修复. 本文选取11种非离子型和3种离子型表面活性剂对多环芳烃(PAHs,菲、芘、苯并[a]芘)污染土壤进行洗脱研究,筛选出洗脱效果较好的表面活性剂,并深入探索表面活性剂浓度、洗脱时间、固液比等因素以及表面活性剂的复配对土壤PAHs增效洗脱的影响,旨在比选出一种高效洗脱土壤PAHs的表面活性剂并对其洗脱方法进行优化. 结果表明:①表面活性剂浓度为10 g/L、固液比为1∶20条件下,聚氧乙烯醚-10(NSF10)的去除率最高,达到78%;其次为曲拉通X-100(TX-100)和吐温80(TW-80),去除率分别为76.7%和73.4%. ②随着表面活性剂添加浓度的增加,土壤PAHs的去除率增大,当表面活性剂浓度超过5 g/L时,PAHs去除率的增幅减缓,可见,5 g/L是相对有效且经济的表面活性剂添加浓度. ③当洗脱时间为16 h时,NSF10对PAHs的洗脱达到平衡,继续延长洗脱时间,洗脱效果并未增强. ④增加NSF10用量有利于洗脱,固液比1∶40是最优固液比,此时PAHs的去除率已达到固液比为1∶100时的85.2%. ⑤非离子表面活性剂NSF10、TX-100、TW-80与阴离子表面活性剂SDS分别以体积比9∶1进行复配时均取得了优于单一活性剂的洗脱效果,NSF10与SDS体积比为7∶3时,增溶洗脱效果最为明显,比单一表面活性剂提高了18.2%. 研究显示,NSF10是一种高效的PAHs洗脱剂,添加浓度为5 g/L、洗脱时间为16 h、固液比为1∶40是其最优参数选择,其与SDS以体积比7∶3进行复配可进一步提升增溶洗脱效果.      

表面活性剂对二嗪磷在不同土壤中吸附迁移的影响

采用批量平衡法和薄层层析法, 分别研究了不同浓度的3种表面活性剂十二烷基苯磺酸钠(SDBS)、Tween80和十六烷基三甲基溴化胺(CTAB) 对二嗪磷在湖南省具有代表性的6大土类、9种不同母质土壤中吸附和迁移性能的影响. 结果表明, SDBS能够明显地降低各种土壤对二嗪磷的吸附, 促进二嗪磷的迁移作用, 并且吸附平衡系数(Kd)、比移值(Rf)分别随SDBS浓度增大而增大、减小.浓度成显著的负相关和正相关关系.Tween-80和CTAB对二嗪磷在土壤中的吸附和迁移表现出一定的相似性, Tween-80浓度在0.1~2倍临界胶束浓度(CMC)范围内(CTAB浓度为0.80~87.43 mg·L-1), 其Kd值、Rf值分别随表面活性剂浓度增大而增大、减小, 而Tween-80浓度在2~5倍临界胶束浓度的范围内(CTAB浓度为87.43~191.60 mg·L-1.), 则出现与之相反的变化趋势.