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.     

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.     

不同链长的聚醚铵阳离子协同插层对蒙脱土性能的影响

为了制备高性能的聚合物/蒙脱土纳米复合材料, 必须对蒙脱土(MMT)进行有机改性来改善蒙脱土表面的疏水性、提高蒙脱土与聚合物之间的相容性, 同时也需要尽可能地增大蒙脱土的层间距. 为此, 提出了一种采用不同链长的聚醚铵阳离子协同插层MMT 的新方法, 即采用D2000(或T5000)聚醚铵盐与D400 聚醚铵盐协同插层MMT, 并采用X射线衍射分析(XRD)和热重分析(TGA)研究了协同插层对改性MMT 的层间距、有机含量以及耐热性的影响. 另外, 也研究了插层过程中的搅拌方式和D400 聚醚铵盐多次插层对改性MMT 的层间距、有机含量等的影响. 研究结果表明,采用长链聚醚铵阳离子协同插层更有利于提高D400 聚醚铵盐改性MMT 的层间距和有机含量; T5000 协同插层MMT中总的有机含量(64.06%)进一步增加, 这可能是因为T5000 的支链在MMT 层间形成的笼型结构既提供了更大的空隙,又起到了屏蔽作用, 同时也得到了较大的层间距(6.86 nm).     

正丁胺对苯膦酸铜的插层反应研究

分别采用溶液搅拌和超声的方法,研究了有机正丁胺分子对苯膦酸铜的插层反应.对插层复合物进行了红外光谱(IR)、X射线粉末衍射(XRD)和热重分析等测试及结构分析.结果表明,有机正丁胺的插入使得苯膦酸铜的层间距增大.     

正丁胺对晶态层状苯乙烯基膦酸-磷酸氢锆的插层研究

合成了晶态层状有机-无机多功能材料苯乙烯基膦酸-磷酸氢锆(α-ZPPVPA),并研究了正丁胺(BA)对α-ZPPVPA的插层性能。用元素分析、XRD、IR、TG、SEM和TEM等分析方法对α-ZPPVPA及其插层化合物α-ZPPVPA-BA进行了结构表征和形貌分析。结果表明,正丁胺成功地插入了α-ZPPVPA层板之间,层间距为2.41 nm,正丁胺的插入使α-ZPPVPA的层间距(1.66 nm)增大了0.75 nm,插入的正丁胺在α-ZPPVPA中呈双分子层排列,且苯乙烯基侧链不饱和双键的存在不影响α-ZPPVPA与正丁胺的插层反应。     

聚萘并噁嗪/蒙脱土纳米复合材料的制备与表征

用原位插层反应法地制备了聚萘并嗪 蒙脱土纳米复合材料 .采用X ray衍射 (XRD)及透射电镜(TEM)研究复合材料中蒙脱土硅酸盐片层间距 ,发现硅酸盐片层间距由 1 2 6nm扩增至 5 88nm以上 .同时研究了该复合材料的耐热性 ,并探讨了复合材料的结晶行为     

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。     

层状(脯氨酸-N-甲基膦酸-磷酸氢)锆的合成及插层性能研究

以高结晶度制备了层状(脯氨酸-N-甲基膦酸-磷酸氢)锆(α-ZPMPP)晶体(层间距为1.52nm),并研究了其常温下对正丁胺的插层性能,用元素分析、IR、XRD和TG-DSC热分析对α-ZPMPP及其插层复合物进行了表征.结果表明,层状α-ZPMPP具有形成超分子主-客体化合物的插层性能,正丁胺客体分子在主体底物中形成单分子层,并插入α-ZPMPP中,使层间距增大0.45nm,插入的正丁胺可在150～250℃被脱除.     

酸性橙插层锌铝水滑石的组装及其结构与性能

采用共沉淀法合成酸性橙阴离子插层锌铝水滑石(Zn/Al-AO7 LDHs),研究不同pH值及原料金属离子配比对产物结构的影响,利用X射线粉末衍射(XRD),热分析(TG-DTA),傅里叶变换红外(FT-IR)等表征手段,对插层产物的结构进行表征,确定了制备酸性橙插层锌铝水滑石的最适宜条件.用量子化学的B3PW91/6-31G(d,p)方法对Zn/Al-AO7 LDHs模型分子的空间几何构型进行了优化,通过结构组合得到的层间距为2.33 nm,接近XRD测试得到的层间距,从而说明了酸性橙离子在水滑石层板间的排列方式.进一步以甲酰胺为溶剂对水滑石层板进行剥离,得到澄清溶液,根据剥离产物的XRD谱可以确定剥离实验成功.     

烷基季铵盐插层剂的合成及应用

Three novel intercalation agents were synthesized for the first time, which arose from oleic acid diethylenetriamine or triethylenetetramine 3 - chloro - 2 - hydroxypropy trimethylammonium choride (CHPTA) and chloroethanol. Organophilic vermicullites were synthesized from sodium type vermiculite by cation exchange with new intercalation agents. The results of X - ray diffraction study showed that the gallery distance of the organophilic vermiculite was enlarged from 1 nm to 5 nm or more. A new idea of making design for intercalation agent was provided.     

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%。     

三氧化钼/苯胺层状复合材料的制备

以三氧化钼为无机主体, 用十二烷基胺对三氧化钼层间进行改性, 成功地制备了三氧化钼/苯胺层状复合材料. X射线衍射、元素分析、扫描电子显微镜、红外光谱测试及差热分析结果表明, 苯胺分子已成功地插入三氧化钼层间, 所得复合物化学式为[ANI]0.4MoO3. 插层后, 三氧化钼仍保持规则有序的层状结构, 其层间距扩大至1.318 nm. 讨论了无机主体与有机客体之间的相互作用、苯胺在层间的可能排布形式以及苯胺插入层间的反应机理.     

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。     

Alpha-CuV2O6 nanowires: hydrothermal synthesis and primary lithium battery application

We report on the synthesis, characterization, and electrochemical lithium intercalation of alpha-CuV2O6 nanowires, mesowires, and microrods that were prepared through a facile hydrothermal route. The diameters of the as-synthesized alpha-CuV2O6 nanowires, mesowires, and microrods were about 100 nm, 400 nm, and 1 microm, respectively. It was found that by simply controlling the hydrothermal reaction parameters, such as the reagent concentration and the dwell time, the transformation of microrods to nanowires was readily achieved via a "ripening-splitting" mechanism. Electrochemical measurements revealed that the as-prepared alpha-CuV2O6 nanowires and mesowires displayed high discharge capacities (447-514 mAh/g at 20 mA/g and 37 degrees C) and excellent high-rate capability. In particular, the alpha-CuV2O6 nanowires showed capacities much higher than those of alpha-CuV2O6 mesowires, microrods, and bulk particles. The mechanisms for the electrochemical lithium intercalation into the alpha-CuV2O6 nanowires were also discussed. From the Arrhenius plot of lithium intercalation into alpha-CuV2O6 nanowires, the activation energies were calculated to be 39.3 kJ/mol at 2.8 V (low lithium uptake) and 35.7 kJ/mol at 2.3 V (high lithium uptake). This result indicates that the alpha-CuV2O6 nanowires are promising cathode candidates for primary lithium batteries used in long-term implantable cardioverter defibrillators (ICD).     

Intercalation of cobaltammine complex ions into layered manganese oxide

The intercalation of Co(2+), [Co(NH(3))(6)](3+), and [Co(NH(3))(5)Cl](2+) ions into layered manganese oxide (birnessite) was studied by chemical, XRD, SEM, IR, and DTA-TG analyses. The intercalation reaction progressed by a 2:1 or 3:1 ion-exchange mechanism depending on the valence of the starting ions. The oxidation state of cobalt did not change with the intercalation reaction. The intercalation of [Co(NH(3))(6)](3+) ions resulted in an increase of basal spacing from 0.716 to 0.956 nm, giving a layered structure material consisting mainly of platelike particles. The chemical analysis results showed that the structure of [Co(NH(3))(6)](3+) ions was maintained in the interlayer. On the other hand, an H(2)O/NH(3) ligand exchange reaction progressed for the intercalation of [Co(NH(3))(5)Cl](2+) ions, resulting in an increase in the basal spacing from 0.716 to 0.956 nm.     

Redoxable nanosheet crystallites of MnO2 derived via delamination of a layered manganese oxide

This paper reports on the swelling and exfoliation behavior of a layered protonic manganese oxide, H(0.13)MnO(2).0.7H(2)O, in a solution of tetrabutylammonium (TBA) hydroxide and the formation and characterizations of unilamellar two-dimensional crystallites of MnO(2). At low doses of TBA ions, layered manganese oxide was observed to undergo normal intercalation, yielding a TBA intercalated phase with a gallery height of 1.25 nm. With a large excess of TBA ions, osmotic swelling occurred, giving rise to a very large intersheet separation of 3.5-7 nm. In an intermediate TBA concentration range, the sample exhibited a broad X-ray diffraction profile with superimposed diffraction features due to intercalation and osmotic swelling. The component responsible for the broad profile was isolated by centrifuging the mixture twice at different speeds, and the recovered colloid was identified as a pile of MnO(2) nanosheets, corresponding to the individual host layer of the precursor layered manganese oxide. Observations by transmission electron microscopy and atomic force microscopy revealed high two-dimensional anisotropy with a lateral dimension of submicrometers and a thickness of approximately 0.8 nm. The nanosheet exhibited broad optical absorption with a peak at 374 nm (epsilon = 1.13 x 10(4) mol(-1) dm(3) cm(-1)). The restacking process of the colloidal MnO(2) nanosheets was followed by aging the colloid at a relative humidity of 95%. The broad diffraction pattern due to the exfoliated sheets weakened with time and eventually resolved into two sharp distinct profiles attributable to a TBA intercalation compound with an intersheet spacing of 1.72 nm and an osmotically swollen hydrate with >10 nm at a very early stage. As drying progressed, the former phase became more abundant without a change in interlayer distance, while the degree of swelling of the latter phase gradually decreased to 2.7 nm that remained unchanged on further aging. Subsequent drying at a lower humidity collapsed the 2.7 nm phase. The resulting single 1.72 nm phase was dehydrated by heating at 150 degrees C to produce a phase with a contracted interlayer spacing of 1.3 nm.     

三聚苯撑乙烯/蒙脱土发光光谱的时间依赖性

用原位插层法制备了插层型的三聚苯撑乙烯/蒙脱土(TPV/MMT)纳米复合材料. 研究了新制备及在室温储存180天后的TPV/MMT纳米复合材料的荧光光谱及蒙脱土层间距的变化情况. 荧光光谱分析表明, 储存180天后, TPV/MMT纳米复合材料的最大发射峰由494 nm蓝移到438 nm, 半峰宽由77 nm增加到104 nm. X射线衍射结果表明, 与新制备的复合材料相比, 蒙脱土的层间距由1.52 nm减小到1.22 nm. 红外光谱分析表明, 室温储存180天后的三聚苯撑乙烯苯环的某些特征峰由1598 和1554 cm-1分别红移到1506和1462 cm-1. 依据相关实验和理论数据探讨了储存180 天前后TPV在蒙脱土中聚集态结构的变化方式.