十六烷基三甲基溴化铵插层氧化石墨结构的分子模拟

利用分子模拟方法研究了十六烷基三甲基溴化铵(C₁₆TAB)分子数对C₁₆TAB/GO插层复合物的结构变化,探讨了C₁₆TAB在GO层间的排列方式,并通过实验数据进行验证.模拟结果表明,优化后GO结构模型的层间距为0.849 nm;C₁₆TAB/GO插层复合物的层间距随着C₁₆TAB分子数的增加呈5个阶梯状逐渐增大,层间距分别为1.56、1.98、2.33、2.76和3.40 nm,插层饱和时C₁₆TAB分子达到28个.实验结果显示,随着C₁₆TAB分子数的增加,C₁₆TAB/GO插层复合物的层间距逐渐增大,插层饱和时为3.40 nm,实验结果与模拟结果能够很好地吻合.C₁₆TAB在GO层间可能的排列方式为1~5层平躺排列或单层平躺、单层倾斜和单层直立,从能量和结构的角度探明了C₁₆TAB在GO层间的最优排列为1~5层平躺排列.     

长链烷基季铵盐插层氧化石墨的结构变化

基于改进的Hummers法制备氧化石墨(GO),并以长链烷基季铵盐(CnTAB)对其进行插层处理;通过改变CnTAB的链长、浓度,得到系列CnTAB/GO插层复合物。采用XRD和元素分析对产物的最大底面间距及CnTAB插入量进行表征。结果表明,随着Cn TAB链长的增长、CnTAB浓度的增大,CnTAB/GO插层复合物的最大底面间距逐渐增大。CnTAB通过离子键作用和疏水键作用插入到GO层间,在GO片层上的吸附规律符合修正型(Modified)Langmuir模型,即CnTAB以单分子层吸附在GO片层上。根据CnTAB/GO插层复合物最大底面间距及CnTAB插入量的变化规律分析,得出CnTAB在GO层间的排布模式有单层平躺模式、类双层平躺模式、单层倾斜模式和单层直立模式。     

长链烷基季铵盐插层氧化石墨的结构变化

基于改进的Hummers法制备氧化石墨(GO),并以长链烷基季铵盐(C_nTAB)对其进行插层处理;通过改变C_nTAB的链长、浓度,得到系列C_nTAB/GO插层复合物。采用XRD和元素分析对产物的最大底面间距及C_nTAB插入量进行表征。结果表明,随着C_nTAB链长的增长、C_nTAB浓度的增大,C_nTAB/GO插层复合物的最大底面间距逐渐增大。C_nTAB通过离子键作用和疏水键作用插入到GO层间,在GO片层上的吸附规律符合修正型(Modified)Langmuir模型,即C_nTAB以单分子层吸附在GO片层上。根据C_nTAB/GO插层复合物最大底面间距及C_nTAB插入量的变化规律分析,得出C_nTAB在GO层间的排布模式有单层平躺模式、类双层平躺模式、单层倾斜模式和单层直立模式。     

不同分子量壳聚糖对蒙脱土插层复合物的影响

于醋酸溶液中通过溶液插层技术将不同分子量的壳聚糖与钠基蒙脱土进行插层复合,制备了系列壳聚糖/蒙脱土插层复合物. 通过XRD、TEM、FTIR测试技术对插层复合物的结构进行了表征. 结果表明,仅通过醋酸溶液处理,残留的HAc就可使MMT层间距由原来的1.3 nm增加至1.55 nm,并使结构规整性提高;降低壳聚糖分子量有利于MMT层间距增大,并出现更多剥离形态的蒙脱土;当壳聚糖分子量为4.1×104时,最大层间距可达2.48 nm,但进一步降低壳聚糖分子量层间距反而略微减小;红外光谱分析表明,插层复合物中壳聚糖与蒙脱土间存在明显的静电作用. TGA分析结果表明,插层复合物中壳聚糖的含量随分子量的降低而增加,残留的醋酸使插层复合物中壳聚糖的热稳定性能下降.     

蒙脱土/阳离子偶氮染料插层纳米复合物离子交换吸附

从有机阳离子与蒙脱土离子交换吸附原理出发,推导出吸附等温式和表面二维状态方程理论关系,给出了热失重确定吸附量的数据处理方法．选择具有光致变色功能、整个分子共轭的有机阳离子GTL作为插层剂,成功制备了一系列插层纳米复合物．GTL阳离子交换吸附实验数据符合推导出的吸附等温式,插层复合物界面压强π随其含水量增大而线性减小,在较低π下,层间GTL以平行于蒙脱土片层表面的单分子层形态排列;随着π增大,层间GTL以倾斜于蒙脱土片层表面的头尾交指型团聚体形态排列;在更大的π下,层间GTL倾向垂直于蒙脱土片层表面成双分子层排列,其尾端重叠自组装形成超分子共轭纳米结构,层间GTL热稳定性大幅度提高。     

直接置换插层法0.85 nm水合高岭石的制备

以高岭石/尿素插层复合物作为中间相,利用简单的直接置换插层法制备了d001=0.85 nm的水合高岭石。利用X射线衍射、红外光谱、扫描电镜表征处理前后高岭石结构与形貌的变化。结果表明:尿素插层后的高岭石层间距从d001=0.72 nm增大到d001=1.08 nm,经不同温度酸洗或水洗后,插层复合物转变成层间有水分子的水合高岭石(d001=0.85 nm),且高岭石晶粒厚度明显从约25 nm减小到约10 nm。在高温条件下形成的水合高岭石含量最高,90℃水洗时d001=0.85 nm水合高岭石的转化率接近70%,这种水合高岭石具有进一步的置换插层能力,是一种制备其他高岭石插层复合物很好的前驱体。与乙二醇形成d001=1.10nm乙二醇/高岭石插层复合物,其置换率达到100%。     

铵离子插层mos2的制备与表征

以剥层重堆法制备了NH 4/MoS2插层复合物,该复合物可以作为长期储存的单层MoS2,同时也可作为先驱体以便插入其它客体分子制成新的插层复合物.通过XRD、热重分析和元素分析等测试技术对该插层复合物进行了表征.结果表明,MoS2经NH 4插层后,其层间距由0.615nm增加到0.954nm,由元素分析和热重分析得出插层复合物的组成分别为(NH 4)3.1 MoS2 和(NH 4 )2.9 MoS2 . 插层复合物在空气中放置30 d后,其XRD和热重分析的结果表明该插层复合物的储存稳定性良好. 此外,插层复合物的插层程度受氯化铵溶液浓度、反应温度、反应时间等反应条件的影响,质量分数为1.0%的氯化铵溶液, 反应温度30 ℃和反应时间12 h,所得到的NH 4 /MoS2插层复合物层间距最大.     

高岭石-硬脂酸插层复合物的制备及结构模型的提出

以张家口高岭土为原料,通过直接插层与取代相结合的方法制备高岭石-硬脂酸插层复合物。利用X射线粉末衍射、红外光谱、热重及透射电子显微镜对制备产物进行表征。结果表明:硬脂酸插入到高岭石层间,高岭石层间距d001值由0.72 nm增加到4.05~4.37 nm,插层率达到86.9%;反应时间和溶液p H值会对高岭石-硬脂酸插层复合物的层间距及插层率产生影响;甲氧基嫁接在高岭石表面,与硬脂酸分子同时存在于高岭石层间。高岭石经甲醇改性后脱羟基温度明显降低,高岭石羟基活性提高;高岭石-硬脂酸插层复合物的稳定温度在160℃以下。经过硬脂酸插层改性后的高岭石片层,从边缘开始出现卷曲现象,并且部分长条状片层形成类似埃洛石相的纳米卷;对硬脂酸插层高岭石的作用机理进行分析,结合结构计算,提出高岭石-硬脂酸插层复合物的结构模型,该模型可以解释高岭石-硬脂酸插层复合物在不同条件制备产物层间距变化的原因。     

高岭石-硬脂酸插层复合物的制备及结构模型的提出

以张家口高岭土为原料,通过直接插层与取代相结合的方法制备高岭石-硬脂酸插层复合物.利用 X射线粉末衍射、红外光谱、热重及透射电子显微镜对制备产物进行表征.结果表明:硬脂酸插入到高岭石层间,高岭石层间距d₀₀₁值由0.72 nm增加到4.05~4.37 nm,插层率达到86.9%;反应时间和溶液pH值会对高岭石-硬脂酸插层复合物的层间距及插层率产生影响;甲氧基嫁接在高岭石表面,与硬脂酸分子同时存在于高岭石层间.高岭石经甲醇改性后脱羟基温度明显降低,高岭石羟基活性提高;高岭石-硬脂酸插层复合物的稳定温度在160 ℃以下.经过硬脂酸插层改性后的高岭石片层,从边缘开始出现卷曲现象,并且部分长条状片层形成类似埃洛石相的纳米卷;对硬脂酸插层高岭石的作用机理进行分析,结合结构计算,提出高岭石-硬脂酸插层复合物的结构模型,该模型可以解释高岭石-硬脂酸插层复合物在不同条件制备产物层间距变化的原因.     

三聚磷酸二氢铝与有机胺的插层反应特征

采用IR、XRD、SEM、EDS、DT-TG和滴定实验等技术手段研究主体三聚磷酸二氢铝(ATP)与客体甲胺、乙胺、正丙胺和正丁胺等有机胺的插层反应特性。 实验结果表明,ATP与甲胺、乙胺、正丙胺、正丁胺发生了化学反应,有机胺中的N与ATP层间-OH上的H形成配位键。 这些有机胺通过插层反应改变了ATP的酸性、层间距和热分解温度,但没有改变颗粒的层状形貌。 层间距从0.795 nm增大至1.71 nm,层间距d与有机胺的碳原子数Cn呈线性关系：d=0.229Cn+0.811,R2=0.9986。 有机胺分子链越长则越具有剥离倾向。     

Synthesis and UV absorption properties of 5, 5′-thiodisalicylic acid intercalated Zn−Al layered double hydroxides

5, 5′-Thiodisalicylic acid (TDSA) has been intercalated into a ZnAl-NO₃ layered double hydroxide (LDH) by an ion-exchange reaction. After intercalation of TDSA, the basal spacing in the LDH increased from 0.89 to 1.53 nm, suggesting that the TDSA anions were arranged in the interlayer galleries of ZnAl-TDSA-LDH as a tilted monolayer arrangement of dianions. The samples were characterized by X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FT-IR), thermogravimetry and differential thermal analysis (TGA-DTA), and UV-Visible spectroscopy (UV-Vis). The results show that the NO₃⁻ anions in the precursor have been completely replaced by TDSA anions to give ZnAl-TDSA-LDH having crystalline-layered structure. Detailed studies reveal the presence of a complex system of supramolecular interactions between LDH layers and TDSA anions. TGA-DTA curves suggest that the thermostability of TDSA was markedly enhanced by intercalation in the LDH host. Photostability tests show that the film of ZnAl-TDSA-LDH/PP possessed higher stability to UV radiation than either the film of TDSA/PP or pristine PP.     

Oriented structure of octadecyl acridine orange intercalated in the monolayer and Langmuir–Blodgett film of octadecyl adenine‐thymine base pairs

The oriented structure of acridine orange (AO) in both monolayer and Langmuir–Blodgett (LB) film has been studied by optical waveguide (OWG) spectroscopy using polarized incident light. Mixed monolayer and LB films, consisting of octadecyl acridine orange (C₁₈‐AO) incorporated in stacked base pairs of octadecyl adenine (C₁₈‐Ade) and octadecyl thymine (C₁₈‐Thy), were prepared on a quartz waveguide. Absorption of transverse electric field (TE) polarized light was about twice that of transverse magnetic field (TM) polarized light. Both OWG spectra have λ_max at 500 nm, which is characteristic of monomeric AO molecules. This result strongly suggests that C₁₈‐AO molecules were dispersed uniformly in the mixed monolayer and were excited more effectively by the TE polarized light. Since the absorption moment of AO molecules is related to their long axis, it is proposed that C₁₈‐AO molecules are incorporated in C₁₈‐Ade/C₁₈‐Thy pairs with the long axis parallel to the layer surface. The absorbance at 500 nm was proportional to the number of layers on the waveguide. The dichroic ratio of the absorbance at 500 nm for TE polarized light to that for TM polarized light was constant regardless of the number of layers. The C₁₈‐AO molecules were uniformly incorporated in each layer with the long axis relatively parallel to the layer surface. Copyright © 2004 John Wiley & Sons, Ltd.     

Intercalation behavior of n-alkylamines into an A-site defective layered perovskite H2W2O7

Intercalation behavior of n-alkylamines into a protonated form of an A-site defective layered perovskite H₂W₂O₇ has been investigated. Results from XRD indicate these materials are layered with the corresponding interlayer spacing governed by the n-alkylamine chain length, and a reversible intercalation and deintercalation property is observed among these intercalation compounds. The IR spectra of the intercalation compounds with n-alkylamines clearly show that n-alkyl chains possess an all-trans conformation, and H₂W₂O₇ accommodate n-alkylamines (C_nH_2n+1NH₂: n=3, 4, 7, 8, 12, 16) to form intercalation compounds via an acid-base mechanism. A linear relationship between the interlayer distance and the number of carbon atoms in n-alkyl chains is observed to show a bilayer arrangement of the n-alkyl chains with a tilt angle of ∼71.6°. Elemental analysis studies reveal that the amounts of intercalated n-alkylamines are about 2.0 mol per [W₂O₇]. Despite the surface geometry of H₂W₂O₇ is almost identical to those of layered perovskites H₂[A_n−1B_nO_3n+1], the amounts of intercalated n-alkylamines of them are different. A reasonable explanation is given through our research.     

Formation and thermal decomposition of pyridine intercalates of α- and γ-zirconium phosphates

The intercalation of pyridine into α-ZrP takes place with an accompanying uptake of one more mole of water to form a dihydrate Zr(HPO₄)_1.55(C₅H₅NHPO₄)_0.45 · 2 H₂O which has an interlayer spacing of 10.9 Å and contains two types of water with different thermostabilities. The pyridine intercalate of γ-ZrP with 12.3 Å spacing is formed by the replacement of interlayer water by the gest molecules without any appreciable change in interlayer spacing and its composition is Zr(HPO₄)_1.56 (C₅H₅NHPO₄)_0.44 · 0.7 H₂O. The α-intercalate undergoes dehydration at below 140°C, accompanied by its separation into a pyridine-free phase (ζ-ZrP) and a pyridine enriched one, and this dehydration is immediately followed by the desorption of pyridine, resulting in the overall conversion of the initial phase to ζ-ZrP. The γ-intercalate, on the other hand, releases its water without any phase separation at similar temperatures but its depyridination temperature at 250°C is about 110°C higher than that for the other. A molecular packing model is proposed to explain the interlayer spacings, compositions, and thermal decomposition properties of both intercalates.     

Stable UV absorption material synthesized by intercalation of squaric acid anion into layered double hydroxides

A novel UV absorption material of squaric acid (SA) anion (O₄O₄^2?) intercalated layered double hydroxides (LDHs) was successfully synthesized by the co-precipitation method. After intercalation, the interlayer distance of MgAl-SA-LDHs increased to 1.04 nm compared to those of MgAl-CO₃-LDHs and SA anions present in form of a monolayer in the interlayer of LDHs. Thermal stability of SA clearly enhanced by the intercalation and the suppression of the deintercalation ability of MgAl-SA-LDHs was superior to that of 4-hydroxy-3-methoxybenzoic acid intercalated LDHs. The results of UV-DRS indicate the potential application of MgAl-SA-LDHs as UV absorbers.     

A novel way to study the initial stages of soap-free emulsion polymerizations: The intercalation of polystyrene oligomers into hydrotalcite

The dominant species in the early stages of an emulsifier-free emulsion polymerization of styrene has been found to be an oligomer of two to three monomer units using a novel trapping technique. This involved the intercalation of charged primary oligomers between the layers of a hydrotalcite, [Mg₄Al₂(OH)₁₂]²⁺[A]^2- (where A = dianion). Hydrotalcites are an important class of lamellar, inorganic compounds whose interlayer spacing can be mod-ified by anion exchange. Our approach first involved preparing a hydrotalcite precursor in which the layers were propped apart by an organic dianion (terephthalate = TA). This material was then used to capture the negatively charged polystyrene oligomers from the emulsion polymerization reaction mixture. We found that TA was rapidly ion-exchanged for the charged oligomers. The resulting pillared hydrotalcite material was characterized using XRD and SEC. We found that the interlayer spacing between the hydroxide layers increased to 23.2 Å on exposure to the emulsion reaction mixture. This represents an interlayer expansion of 18.3 Å (after subtraction of the hydroxide layer contribution), which is cnsistent with intercalation of oligomers with two to three monomer units arranged in a bilayer. This size estimate was confirmed by the results of size exclusion chromatography. © 1995 John Wiley & Sons, Inc.