2-[3-(4-甲氧基苯氧基)丙基]-1,3-二乙酰硫基丙烷的合成

自组装单层膜(SAMs)技术是自20世纪80年代以来快速发展起来的一个新型有机成膜技术,它是通过表面活性剂的头基与基底之间产生化学吸附,在界面上自发形成的有序的单分子层[1].     

氨基功能化KIT-6两步后嫁接制备及其吸附Pb2+性能

以正硅酸乙酯作为硅源,三嵌段共聚物P123作为模板剂制备介孔材料KIT-6。再采用后嫁接法,先将3-氯丙基三甲氧基硅烷嫁接到KIT-6上,再用聚乙烯亚胺(PEI)进一步嫁接,合成出PEI功能化的PEI/KIT-6。用傅立叶变换红外光谱分析(FTIR)、X射线衍射(XRD)、热重分析(TGA)、元素分析、N_2吸附-脱附、扫描电镜等手段进行结构的表征。用电感耦合等离子体光谱(ICP)测定材料的Pb~(2+)吸附性能。结果表明氨基的表面平均负载量为0.374 mmol·g~(-1),并且改性后KIT-6仍具有高度有序性,并未出现孔道堵塞的现象。PEI/KIT-6在投加量为1 g·L~(-1),室温条件下,吸附100 mg·L~(-1) Pb~(2+)的最佳p H值为6.0;吸附容量伴随温度的提高先增加后减小,最佳反应温度为35℃;材料在120 min内可以达到吸附平衡,吸附过程符合拟二级动力学方程;Langmuir和Freundlich模型均能较好地描述该吸附过程。吸附倾向于发生单分子层的化学吸附。     

基于活性金电极上硫代水杨酸自组装单分子层的电化学表面增强拉曼光谱

采用原位电化学表面增强拉曼光谱(EC-SERS)研究了硫代水杨酸(TSA)吸附在活性Au电极表面的自组装单分子层(SAMs).TSA在活性Au表面的化学吸附及不同酸碱度下的TSA浸饰单层膜的SERS光谱,表明随pH值的增加,峰强呈现2个不同的下降阶段.通过EC-SERS考察不同电富集时间和电位的影响,显示在酸性介质和0.7 V及70 s富集时间下,可以获得最大EC-SERS信号,并随着电位负移,信号逐渐减弱,直至基本消失,表明TSA分子在Au表面排布状态会随外加条件的改变而发生变化.通过计算TSA在不同pH值下的分布分数以及探针分子在不同电位下的增强因子(EF),结合SERS和EC-SERS的变化走势对比,得出TSA在活性Au表面自组装形成单分子层/膜的机理,指出由于TSA不同的电化学吸附取向,以及高负电位下的还原/脱附作用,使得Au表面拉曼活性降低,造成EF显著减小,不可逆地失去了SERS的活性.     

Cu-BTC/PVDF杂化膜的原位掺杂制备及增强的染料吸附性能

将Cu-BTC颗粒与聚偏氟乙烯(PVDF)溶液共混,原位掺杂制备了Cu-BTC/PVDF杂化膜,利用扫描电子显微镜(SEM)、X射线衍射仪、热重分析仪和傅里叶变换红外光谱仪等对杂化膜的结构进行了表征,并对杂化膜的亲/疏水性质、膜孔隙率以及膜水通量进行了测定,探讨了Cu-BTC的掺杂量对杂化膜结构和性质的影响.结果表明,Cu-BTC的存在使PVDF薄膜的成核机理发生改变,降低了PVDF膜孔尺寸,提高了膜表面亲水性和水通量.在对刚果红(CR)的吸附实验中,Cu-BTC/PVDF杂化膜表现出显著增强的吸附活性,且随着Cu-BTC掺杂量的增加,Cu-BTC/PVDF对CR的吸附性能逐渐增强.吸附热动力学拟合结果表明,吸附过程以Langmuir单分子层吸附和化学吸附为主要特征.     

硅胶表面上脂肪酸蒸气吸附膜

应用Gibbs方程由甲酸、乙酸和丙酸蒸气在硅胶上的吸附等温线计算了吸附膜的表面压力(π)与每个吸附分子所占面积(σ)间的关系(π～σ图).所得曲线与不溶物在溶液表面上的结果相似,均表现出有“液态扩张膜”“转变膜”和“液态凝聚膜”.不同的是,不溶物只能形成单分子层膜,而硅胶表面上的脂肪酸吸附膜则是多分子层的.蒸气吸附膜由单层向多层的转变,恰与π～σ图上的“液态扩张膜”向“转变膜”的转变相对应.吸附焓(△H)与吸附熵(△S)的计算结果表明,在此转变附近AH和AS发生急剧变化.     

球形大孔树脂担载PEI对CO2的吸脱附行为

以球形大孔树脂（SMR）、聚乙二醇分别作聚乙烯亚胺（PEI）的载体和黏结剂,制得PEI／SMR吸附材料．考察了PEI／SMR材料对CO2的吸脱附性能,并对吸附过程进行了分析．研究结果表明：（1）当PEI担载量为40％、吸附温度为30℃时,PEI／SMR样品对C02的平衡吸附量达4．02mrnol／g,并具有良好的吸脱附循环性能;（2）当模拟烟道气中的湿度为14．5％时,由于部分H20参与了化学反应,使得PEI／SMR样品对C02的平衡吸附量提高了5．7％;（3）C02在PEI／SMR的吸附,先是CO2分子吸附在SMR材料的表面,然后被吸附的CO2分子从表面扩散进入PEI主体相进行化学反应．     

聚乙烯亚胺表面改性硅藻土及其对苯酚吸附特性的研究

使用紫外吸收光度法研究了硅藻土对聚乙烯亚胺(PEI)的等温吸附;采用浸渍法,用PEI对硅藻土进行了表面改性;使用4-氨基安替比林光度法研究了经PEI表面改性的硅藻土对苯酚的捕集行为.研究结果表明,凭借强烈的静电相互作用,表面带负电荷的硅藻土粉体对阳离子性大分子PEI具有很强的吸附能力,等温吸附满足Freundlich吸附方程;经PEI表面改性后,硅藻土粉体表面的电性发生了根本性改变,且等电点由pH=2.0移至pH=10.5;在中性溶液中,改性粉体通过氢键作用与静电相互作用的协同,对水溶液中的苯酚会产生很强的捕集作用,饱和吸附量可达92 mg/g;在酸性溶液中改性粉体通过氢键相互作用,对水溶液中的苯酚产生一定的吸附作用,但由于PEI分子链高度的质子化,氮原子对苯酚的氢键相互作用很弱,吸附量很低.     

缓蚀剂吸附行为的电化学及AFM力曲线研究

结合极化曲线,微分电容曲线测试和AFM力曲线技术研究了直链十二胺对氯化钠溶液中铜镍合金的缓蚀行为以及吸附机理。结果表明:十二胺在合金表面形成单分子层吸附膜而起到缓蚀作用。十二胺浓度越大,吸附膜越致密,缓蚀率越高,力曲线上测得的粘附力值也越大。质子化的十二胺在荷负电的合金表面的吸附使电极零电荷电位正移,电荷屏蔽作用使得AFM力曲线上探针与试样之间的长程静电斥力减小。     

复合型螯合吸附材料PEI/SiO2对铜离子吸附性能的研究

通过γ-氯丙基三甲氧基硅烷的媒介, 将聚乙烯亚胺(PEI)偶联接枝到硅胶微粒表面, 制备了复合型螯合吸附材料PEI/SiO2;研究了PEI/SiO2对Cu2 的吸附性能. 复合型螯合吸附材料PEI/SiO2对Cu2 具有强的螯合吸附能力;等温吸附数据符合Langmuir方程, 且吸附量随温度升高而增大;pH对吸附量有很大的影响, pH 7时, 吸附量最高.     

基因载体材料聚乙烯亚胺与磷脂酰胆碱脂质体的相互作用对膜结构的影响

采用动态光散射、荧光光谱、zeta电位测定和等温滴定量热技术分析了分子量分别为25000,10000和1800的聚乙烯亚胺(PEI)与二油酰磷脂酰胆碱(DOPC)脂质体的相互作用及其对脂质体膜内环境极性和膜通透性的影响.结果表明,PEI通过氨基与DOPC的磷脂基团和胆碱基团产生氢键或范德华作用,从而与脂质体结合形成复合物;低浓度PEI(0.075 mg/mL)导致DOPC脂质体的聚集和表面电位的增加,但未引起脂质体膜融合和表面电位反转;进一步增加PEI的浓度对脂质体表面电位的影响很小,而结合在表面的PEI分子链之间的排斥作用阻碍了脂质体聚集.PEI分子与DOPC脂质体的结合降低了脂质分子碳氢链的堆积密度和脂质体膜内环境的疏水性,从而增强了钙黄绿素和槲皮素在脂质体膜中的通透性.PEI与DOPC脂质体的相互作用具有明显的分子尺寸效应,增大PEI的分子量可以增强与脂质体的相互作用及对脂质体膜结构的影响.     

Enhanced Cu(II) and Cr(VI) biosorption capacity on poly(ethylenimine) grafted aerobic granular sludge

The biosorption characteristics of cations and anions from aqueous solution using polyethylenimine (PEI) modified aerobic granules were investigated. Fourier transform infrared (FTIR) and X-ray photoelectron spectroscopy (XPS) analysis exhibit the presence of PEI on the granule surface. Compared with the raw granule, the modified aerobic granules with PEI showed a significant increase in sorption capacity for both metal ions. The monolayer biosorption capacity of granules for Cu(II) and Cr(VI) ions was found to be 71.239 and 348.125mg/g. The optimum solution pH for adsorption of Cu(II) and Cr(VI) from aqueous solutions was found to be 6 and 5.2, respectively. The biosorption data fitted better with the Redlich-Peterson isotherm model. FTIR showed chemical interactions occurred between the metal ions and the amide groups of PEI on the biomass surface. XPS results verified the presence of Cr(III) on the biomass surface, suggesting that some Cr(VI) anions were reduced to Cr(III) during the sorption.     

Stainless steel modified with poly(ethylene glycol) can prevent protein adsorption but not bacterial adhesion

The surface of AISI 316 grade stainless steel (SS) was modified with a layer of poly(ethylene glycol) (PEG) (molecular weight 5000) with the aim of preventing protein adsorption and bacterial adhesion. Model SS substrates were first modified to introduce a very high density of reactive amine groups by the adsorption of branched poly(ethylenimine) (PEI) from water. Methoxy-terminated aldehyde-poly(ethylene glycol) (M-PEG-CHO) was then grafted onto the PEI layers using reductive amination at the lower critical solution temperature (LCST) of the PEG in order to optimize the graft density of the linear PEG chains. The chemical composition and uniformity of the surfaces were determined using X-ray photoelectron spectroscopy (XPS) and time-of-flight static secondary ion mass spectrometry (ToF-SSIMS) in the imaging mode. The effects of PEI concentration and different substrate pre-cleaning methods on the structure and stability of the final PEG layer was examined. Piranha solution proved to be the most effective method for removing adventitious hydrocarbon contamination, compared to cleaning with ultrasonication in organic solvents, and was the SS substrate that produced the most stable and thickest PEI layer. The surface density of PEI was shown to increase with increasing PEI concentration (up to 30 mg/ml), as determined from XPS measurements, and subsequently produced the PEG layer with the highest density of attached chains. In model experiments using β-lactoglobulin no protein adsorption was detected on the optimized PEG surface as determined by XPS and ToF-SSIMS analysis. However, neither the adhesion of a Gram-negative (Pseudomonas sp.) nor a Gram-positive (Listeria monocytogenes) bacterium was affected by the coating as equal numbers adhered to all surfaces tested. Our results show that preventing protein adsorption is not a prerequisite stopping bacterial adhesion, and that other mechanisms most likely play a role.     

Dispersion of TiN in aqueous media

The dispersion of TiN powders in aqueous media was studied through XPS, zeta potential, adsorption, sedimentation, and rheology measurements. XPS showed that there are TiO2, TiN, and TiOxNy sites on the TiN particle surface. In the absence of dispersant, the isoelectric point (pH(IEP)) of the TiN particles was at pH 2.2. Based on the surface properties of TiN particles, a cationic polymer, polyethylene imine (PEI), was selected as a dispersant. In the presence of PEI, the pH(IEP) shifted from pH 2.2 to pH 11.10. It was evidenced that TiN slurries could be stabilized around pH 9.50 with 1-2 wt% PEI as dispersant. Subsequently, TiN slurries with solid content as high as 57 vol% were developed and exhibited dilatant rheological behavior at high shear rate. The results showed that PEI is an effective dispersant for TiN in aqueous media.     

Surface stress, thickness, and mass of the first few layers of polyelectrolyte

The effects of surface stress and mass loading upon the adsorption of polyelectrolytes onto flexible silicon micromechanical cantilever sensors (MCSs) were studied in situ. A self-assembled monolayer of 2-mercaptoethylamine chloride (2-MEA) on gold was used to achieve single-side adsorption on the MCS. Such a preparation gave a positive surface potential, whereas a bare SiOx surface gave a negative surface potential. Wide scan X-ray photoelectron spectroscopy confirmed that the adsorption of polystyrenesulfonate (PSS) and polyallylamine hydrochloride (PAH) followed the general rule expected from the electrostatic interaction between the substrate and the polyelectrolyte, whereas the adsorption polyethyleneimine (PEI) did not. The adsorption of PAH on SiO(x) from a 3 mM water solution containing 1 M NaCl was associated with a deflection of the MCS toward the polyelectrolyte monolayer (tensile surface stress) owing to the hydrogen bonding between neighboring amino groups. Here, a surface stress change of 1.4 +/- 0.1 N/m was estimated. The adsorption of PSS from a 3 mM water solution containing 1 M NaCl on a 2-MEA surface induced a deflection of the MCS away from the polyelectrolyte layer (compressive stress), toward the SiO(x) side. Here, a surface stress change of 3.1 +/- 0.3 N/m was determined. The formation of a PAH layer on top of the PSS layer resulted in a deflection of the MCS toward the PAH layer. This indicated that the adjacent PSS layer was deswelling, corresponding to a surface stress change of 0.5 +/- 0.1 N/m.     

Structure, morphology and interface properties of ultrathin SnTTBPP(OH)2-films adsorbed on Ag(100)

The molecular interaction of dihydroxo[5,10,15,20-tetrakis(4-tert-butyl-phenyl)porphyrinato]-tin(IV) (SnTTBPP(OH)(2)), the structural order and growth of ultrathin films on Ag(100) have been studied by means of low-energy electron diffraction (LEED) and synchrotron based photoelectron spectroscopy, i.e., X-ray photoemission (XPS) and near-edge X-ray absorption fine structure (NEXAFS/XANES) spectroscopy. For the first time, monolayer adsorption of a metalloporphyrin with octahedral coordination of the metal center by two additional axial hydroxo ligands is investigated in a multi-technique study. The delicate balance of molecule-substrate interactions and intermolecular interactions leads to the formation of a densely-packed organic monolayer which is commensurate with the Ag(100) substrate. From NEXAFS linear dichroism an almost coplanar orientation of the porphyrin system is derived. XPS and NEXAFS clearly indicate that the axial hydroxo ligands are cleaved in monolayer films, i.e., upon adsorption to the Ag substrate. With increasing film thickness orientational order gets lost and leads to polycrystalline growth for thicker films as confirmed by scanning X-ray transmission microscopy (STXM).     

Interfacial chemistry of adhesives on hydrated aluminium and hydrated aluminium treated with an organosilane

The adsorption of a commercial adhesive and two of its major components—an amine curing agent [2,4‐toluene diisocyanate urone (TDI urone)] and an adhesive prepolymer resin [diglycidyl ether of bisphenol A (DGEBA)]—on a hydrated aluminium surface and the hydrated surface coated with γ‐glycidoxypropyltrimethoxysilane (GPS) has been investigated by x‐ray photoelectron spectroscopy (XPS) and time‐of‐flight secondary ion mass spectrometry (ToF‐SIMS). The study of TDI urone adsorption indicated that adsorption was of the chemisorption type, and a specific interaction involving this molecule and the GPS immobilized on the hydrated aluminium surface was identified. From XPS and ToF‐SIMS data it was found that the types of interaction of the curing agent with the bare substrate were of the donor–acceptor type. Study of the DGEBA adsorption showed different‐shaped isotherms for the bare and the GPS‐coated substrates. It was found that the typical Langmuir isotherm type was obtained for the GPS‐coated substrate whereas no adsorption plateau was observed for the bare substrate within the concentration range studied. This resulted from a change in the conformation of the DGEBA molecule on the substrate when the concentration of DGEBA solution was increased. The bonding of DGEBA with both types of substrates was assumed to be via acid–base interactions (i.e. donor–acceptor interactions). Adsorption of the commercial adhesive on the hydrated surfaces was of BET Type IV form, rather than the simple monolayer adsorption isotherm (Langmuir type). This indicates multilayer adsorption, presumably in the pores of the hydrated substrate, as a result of a process analogous to adsorption condensation. Copyright © 2004 John Wiley & Sons, Ltd.     

The reaction of tetrakis(dimethylamido)titanium with self-assembled alkyltrichlorosilane monolayers possessing -OH, -NH2, and -CH3 terminal groups

The reactions of tetrakis(dimethylamido)titanium, Ti[N(CH(3))(2)](4), with alkyltrichlorosilane self-assembled monolayers (SAMs) terminated by -OH, -NH(2), and -CH(3) groups have been investigated with X-ray photoelectron spectroscopy (XPS). For comparison, a chemically oxidized Si surface, which serves as the starting point for formation of the SAMs, has also been investigated. In this work, we examined the kinetics of adsorption, the spatial extent, and stoichiometry of the reaction. Chemically oxidized Si has been found to be the most reactive surface examined here, followed by the -OH, -NH(2), and -CH(3) terminated SAMs, in that order. On all surfaces, the reaction of Ti[N(CH(3))(2)](4) was relatively facile, as evidenced by a rather weak dependence of the initial reaction probability on substrate temperature (T(s) = -50 to 110 degrees C), and adsorption could be described by first-order Langmuirian kinetics. The use of angle-resolved XPS demonstrated clearly that the anomalous reactivity of the -CH(3) terminated SAM could be attributed to reaction of Ti[N(CH(3))(2)](4) at the SAM/SiO(2) interface. Reaction on the -NH(2) terminated SAM proved to be the "cleanest", where essentially all of the reactivity could be associated with the terminal amine group. In this case, we found that approximately one Ti[N(CH(3))(2)](4) adsorbed per two SAM molecules. On all surfaces, there was significant loss of the N(CH(3))(2) ligand, particularly at high substrate temperatures, T(s) = 110 degrees C. These results show for the first time that it is possible to attach a transition metal coordination complex from the vapor phase to a surface with an appropriately functionalized self-assembled monolayer.     

Functional membranes prepared by layer‐by‐layer assembly and its metal ions adsorption property

PVDF/(PEI‐C/PAA)_n functional membranes were prepared by layer‐by‐layer (LbL) assembly, and their heavy metal ions adsorption capability was investigated. The changes in the chemical compositions of membrane surfaces were determined by X‐ray photoelectron spectroscopy (XPS). XPS results show that the surface of the PVDF membrane can be alternatively functionalized by PEI‐C and PAA. The membrane surface hydrophilicity was evaluated through water contact angle measurement. Contact angle results show that the surface hydrophilicity of the membrane surface depends on the outermost deposited layer. Morphological changes of membrane surfaces were observed by scanning electron microscopy (SEM). The water fluxes for these membranes were elevated after modification. The performances of the PVDF/(PEI‐C/PAA)_n membranes on the adsorption of copper ions (Cu²⁺) from aqueous solutions were investigated by inductively coupled plasma (ICP). The results indicate that the PVDF/(PEI‐C/PAA)_n functional membranes show high copper ions adsorption ability. Copyright © 2010 John Wiley & Sons, Ltd.     

Influence of Poly(ethylenimine) on the Monolayer of Oleic Acid at the Air/Water Interface

The effect of poly(ethylenimine) (PEI) dissolved in water on the surface pressure-area isotherm of oleic acid (OA) at the air/water interface was investigated. On a concentrated PEI solution, the isotherm of the OA monolayers exhibited a noticeable difference as a function of subphase pH. PEI caused the collapse pressure of the OA monolayer to increase up to 45 mN/m, due to a stronger acid-base-type interaction occurring between the amine group of the PEI and the carboxyl group of OA; on a pure water subphase, the collapse pressure was;28 mN/m. On the other hand, owing to a stronger OA-PEI interaction, the OA monolayers favored a liquid-expanded state more on the PEI-containing water subphase than on the pure water. From the QCM measurement, each OA molecule appeared to interact, on average, with 4.3-5.8 ethylenimine repeating units at basic pHs. We also found that OA multilayers could be assembled on a hydrophilic substrate by a Z-type Langmuir-Blodgett (LB) deposition in a PEI-containing subphase at basic pHs. The ATR-IR spectral data revealed that, in a Z-type LB film, the headgroup of OA was mostly present as carboxylate, interacting in an ionic state with the protonated amine groups of PEI. In acidic conditions, neither a Y-type nor a Z-type deposition was really accomplished. Nonetheless, the ATR-IR spectral data suggested that OA molecules should exist in a monomeric state in a LB film assembled at acidic pHs without PEI while they would form intermolecular hydrogen bridges and/or dimers in the presence of PEI. Copyright 2000 Academic Press.     

Solid Amine Adsorbent Prepared by Molecular Imprinting and Its Carbon Dioxide Adsorption Properties

A carbon dioxide imprinted solid amine adsorbent (IPEIA‐R) with polyethylenimine (PEI) as a skeleton was conveniently prepared by using glutaraldehyde to cross‐link carbon dioxide‐preadsorbed PEI. As confirmed by FTIR, FT‐Raman, and ¹³C NMR spectroscopy, CO₂ preadsorbed on PEI could occupy the reactive sites of amino groups and act as a template for imprinting in the cross‐linking process. The imino groups formed from the cross‐linking reaction between glutaraldehyde and PEI could be reduced by NaBH₄ to form CO₂‐adsorbable amino groups. The adsorption results indicated that CO₂ imprinting and reduction of imino groups by NaBH₄ endowed the adsorbent with a higher CO₂ adsorption capacity. Compared with PEI‐supported mesoporous adsorbents, the solid amine adsorbent with PEI as a skeleton can avoid serious pore blockage and CO₂ diffusion resistance, even with a high amine content. The solid amine adsorbent with PEI as a skeleton showed a remarkable CO₂ adsorption capacity (8.56 mmol g^?1) in the presence of water at 25 °C, owing to the high amine content and good swelling properties. It also showed promising regeneration performance and could maintain almost the same CO₂ adsorption capacity after 15 adsorption–desorption cycles.