微孔磷酸铝AIPO4-HDA的热分解过程研究

采用差热-热重-质谱(TG-DTA-MS)、粉末X射线衍射(XRD)、红外光谱(FTIR)和固体核磁(Solid-State-MAS-NMR)等技术详细地研究了微孔磷酸铝晶体AlPO4-HDA中模板剂的热分解过程.结果表明,该模板剂的热分解分3步进行:第一步是模板剂和无机骨架之间的部分氢键断裂;第二步为模板剂的Hof-mann降解反应和β-消除反应;第三步是残留积碳的氧化分解反应.固体MASNMR的研究结果表明,随着模板剂的脱出.无机骨架中铝和磷的配位状态发生了变化.     

新型六方铜铝磷酸盐的合成及苯酚催化羟化反应活性的研究

本文采用静态水热合成法合成了一种非水溶性固体铜铝磷酸盐(CuAlPO).研究结果发现,CuAlPO是一种与六方二氧化硅(SiO₂)晶体结构相同的新型铜铝磷盐,在温和反应条件下(30℃),CuAlPO具有较高的苯酚催化羟化反应活性.     

低硅铝比ZSM-5分子筛的合成及其正庚烷裂化反应性能

以氨水为矿化剂,通过添加NH₄⁺离子水热合成了具有较低骨架硅铝比的ZSM-5分子筛。通过X射线衍射(XRD)、扫描电镜(SEM)、固体核磁共振(MAS-NMR)等表征手段,研究了硅源、铝源、矿化剂、阳离子等对ZSM-5分子筛的结晶度、形貌尺寸和骨架硅铝比等的影响,研究了ZSM-5分子筛的骨架硅铝比对正庚烷催化裂化反应的影响。研究表明,投料硅铝比越低,铝原子越难进入到分子筛骨架中;当氨水为矿化剂、正硅酸四乙酯为硅源时可以合成骨架硅铝比较低的氢型ZSM-5分子筛,添加NH₄⁺离子可以增强骨架铝的嵌入,进一步降低分子筛的骨架硅铝比(24.2)。正庚烷裂化反应结果表明,降低分子筛的骨架硅铝比可以提高正庚烷裂化反应的活性,但会降低低碳烯烃的选择性。     

一步处理法制备高水热稳定多级孔ZSM-5分子筛

ZSM-5具有较高的催化活性和独特的择形选择性,因而被广泛用于精细化工和石油炼制等工业过程.但其较小的孔道尺寸导致其在反应中尤其在催化过程中的传质受到影响,从而严重影响催化剂寿命.为了解决反应过程中分子筛中底物及产物的扩散限制问题,近年来关于介微孔复合多级孔道分子筛的研究在分子筛合成领域引起了广泛兴趣,并取得一定进展.但直接合成法存在成本及复杂性问题,因此在量产的分子筛上进行后改性引入介孔表现出明显优势.在这一大类处理过程中,碱处理造介孔因成本低以及可操作性较高而备受青睐.但由于脱硅所形成的介孔往往无序,稳定性较差,因此提高其水热稳定性具有重要意义.文献已有较多报道通过磷元素修饰抑制分子筛在水热环境中脱铝,从而提高分子筛骨架稳定性.但传统的磷元素修饰一般采用后续浸渍法,过程繁琐.本课题组开发了一步法后处理制备高水热稳定多级孔ZSM-5分子筛,将脱硅过程与磷引入过程相结合,以四乙基氢氧化磷(TEPOH)为磷源,直接处理微孔分子筛得到含磷的多级孔分子筛.相比于传统的分子筛磷修饰过程,该磷物种在处理中优先交换分子筛骨架上铝原子附近用来平衡电荷的钠离子,从而增加了磷物种与铝物种相互作用的可能性,提高了稳化骨架的效果.基于此,本文利用氮吸附-脱附、元素分析、X射线粉末衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)、氨程序升温脱附(NH3-TPD)以及27Al和31P固体核磁(NMR)等一系列表征技术,证明该一步后处理法对分子筛催化性能的作用.SEM和XRD结果表明,分子筛在进行各种处理前后,相对结晶度和分子筛形貌变化不大,说明大部分微孔得到保留.TEM测试表明,经过该一步后处理法得到的分子筛实现了介孔的引入,介孔孔径在10–20 nm.元素分析结果表明,几乎所有的磷源物质在该过程中被引入到分子筛上,实现了介孔和磷物种的同时引入.NH3-TPD测试表明,含磷分子筛在老化前后较无磷分子筛具有更高的酸性位密度保留度,说明磷元素对分子筛上的酸性位起到了稳化作用.孔结构特性数据不仅说明了脱硅过程中成功引入介孔,而且含磷分子筛老化前后的介孔特性数据保留度明显高于无磷样品,实现了磷元素对介孔结构的稳化作用.27Al和31P NMR结果从理论上证明了该样品上磷元素对抑制骨架脱铝的稳化效应,证实了分子筛在处理后水热稳定性的提高.基于前期的研究工作,本文完善了磷元素对分子筛稳化作用的机理过程.TEPBr在水热活化过程中转变成磷酸盐,并修饰分子筛的骨架铝以及部分难以避免的非骨架铝.该过程中形成的磷铝物种在后续的水热老化过程中进一步修饰分子筛骨架铝,使骨架铝得到稳化.而在脱硅过程中存在的"反插铝"过程往往使大部分骨架铝位于介孔孔道中,磷元素与铝元素的相互作用同时也对介孔进行了稳化.通过正辛烯和1,3,5-三异丙苯的裂化测试发现,处理后的分子筛由于其优化后的孔道性能和酸性性质,大大提高了底物分子的转化率以及其自身的容碳能力,从而延长了催化寿命.     

一步处理法制备高水热稳定多级孔ZSM-5分子筛（英文）

ZSM-5具有较高的催化活性和独特的择形选择性,因而被广泛用于精细化工和石油炼制等工业过程.但其较小的孔道尺寸导致其在反应中尤其在催化过程中的传质受到影响,从而严重影响催化剂寿命.为了解决反应过程中分子筛中底物及产物的扩散限制问题,近年来关于介微孔复合多级孔道分子筛的研究在分子筛合成领域引起了广泛兴趣,并取得一定进展.但直接合成法存在成本及复杂性问题,因此在量产的分子筛上进行后改性引入介孔表现出明显优势.在这一大类处理过程中,碱处理造介孔因成本低以及可操作性较高而备受青睐.但由于脱硅所形成的介孔往往无序,稳定性较差,因此提高其水热稳定性具有重要意义.文献已有较多报道通过磷元素修饰抑制分子筛在水热环境中脱铝,从而提高分子筛骨架稳定性.但传统的磷元素修饰一般采用后续浸渍法,过程繁琐.本课题组开发了一步法后处理制备高水热稳定多级孔ZSM-5分子筛,将脱硅过程与磷引入过程相结合,以四乙基氢氧化磷(TEPOH)为磷源,直接处理微孔分子筛得到含磷的多级孔分子筛.相比于传统的分子筛磷修饰过程,该磷物种在处理中优先交换分子筛骨架上铝原子附近用来平衡电荷的钠离子,从而增加了磷物种与铝物种相互作用的可能性,提高了稳化骨架的效果.基于此,本文利用氮吸附-脱附、元素分析、X射线粉末衍射(XRD)、扫描电镜(SEM)、透射电镜(TEM)、氨程序升温脱附(NH_3-TPD)以及~(27)Al和~(31)P固体核磁(NMR)等一系列表征技术,证明该一步后处理法对分子筛催化性能的作用.SEM和XRD结果表明,分子筛在进行各种处理前后,相对结晶度和分子筛形貌变化不大,说明大部分微孔得到保留.TEM测试表明,经过该一步后处理法得到的分子筛实现了介孔的引入,介孔孔径在10–20 nm.元素分析结果表明,几乎所有的磷源物质在该过程中被引入到分子筛上,实现了介孔和磷物种的同时引入.NH_3-TPD测试表明,含磷分子筛在老化前后较无磷分子筛具有更高的酸性位密度保留度,说明磷元素对分子筛上的酸性位起到了稳化作用.孔结构特性数据不仅说明了脱硅过程中成功引入介孔,而且含磷分子筛老化前后的介孔特性数据保留度明显高于无磷样品,实现了磷元素对介孔结构的稳化作用.27Al和31P NMR结果从理论上证明了该样品上磷元素对抑制骨架脱铝的稳化效应,证实了分子筛在处理后水热稳定性的提高.基于前期的研究工作,本文完善了磷元素对分子筛稳化作用的机理过程.TEPBr在水热活化过程中转变成磷酸盐,并修饰分子筛的骨架铝以及部分难以避免的非骨架铝.该过程中形成的磷铝物种在后续的水热老化过程中进一步修饰分子筛骨架铝,使骨架铝得到稳化.而在脱硅过程中存在的"反插铝"过程往往使大部分骨架铝位于介孔孔道中,磷元素与铝元素的相互作用同时也对介孔进行了稳化.通过正辛烯和1,3,5-三异丙苯的裂化测试发现,处理后的分子筛由于其优化后的孔道性能和酸性性质,大大提高了底物分子的转化率以及其自身的容碳能力,从而延长了催化寿命.     

SAPO-5分子筛的结构和性能

AlPO_4-5是一种新型多孔磷铝分子筛晶体.由于骨架中不存在SiO_4四面体,PO_4~+AlO_4~-四面体交替排列,骨架呈电中性。Lok等首先报道了磷酸硅铝分子筛(SAPO)的合成.目前已有十几种元素同晶取代的AlPO_4-5分子筛.由于同晶取代,使得电中性的AlPO_4-5分子筛骨架呈电性和离子交换性,加之骨架本身所具有的良好热稳定性和多     

有机弱碱体系中氢型硅铝MCM-41介孔分子筛的合成及表征

以有机胺为碱源合成出硅铝介孔分子筛MCM-41,并将合成产物的性能与采用传统方法(以氢氧化钠为碱源)合成的产物进行了对比.所合成产物经焙烧脱除有机表面活性剂后即为氢型.XRD和TEM结果表明,所合成的产物骨架具有很高的有序度.固体核磁共振结果显示,铝原子以四配位的形式存在于样品的原粉中.经过高温焙烧,有少量骨架铝脱出骨架,转变成六配位形式.程序升温吡啶吸附红外光谱证明焙烧后产物具有一定的表面酸性.     

柠檬酸溶液中NaY分子筛的脱铝行为

硅铝分子筛有机酸配合脱铝是提高其稳定性、引入介孔的一种重要方法.采用X射线衍射、N₂物理吸附、高分辨透射电镜、傅里叶变换红外光谱、²⁷Al和²⁹Si固体魔角自旋核磁共振光谱等方法研究了NaY分子筛柠檬酸脱铝行为.结果表明,柠檬酸浓度对NaY分子筛骨架Al原子的脱出影响尤为显著.反应起始阶段,分子筛骨架铝原子快速脱出,其晶体结构遭到严重破坏.随着反应的进行,分子筛硅铝比和结晶度皆有所增加,表明其骨架结构可能进行了重新排列.75℃下,0.10 mol/L柠檬酸处理2 h的脱铝分子筛样品,与NaY分子筛样品相比,其骨架硅铝比增加了0.6、外表面增加了17 m²·g^-1,脱铝同时产生了大量无定形硅.     

水热合成超细晶粒A-/MxOy固体超强酸

 A-/MxOy是一种新的固体超强酸催化材料,由单价酸根负载于金属氧化物上组成,它不同于传统的固体超强酸SO2-4/ZrO2. 在水热合成的条件下金属盐和碱沉淀剂发生均匀的水解沉淀反应,生成A-/MxOy固体超强酸,这种合成方法被称作“均匀沉淀法”. 采用“均匀沉淀法”可以一步直接合成具有小于10 nm超细晶粒的A-/MxOy固体超强酸催化材料. 对“均匀沉淀法”合成A-/MxOy固体超强酸的影响因素和规律性进行了详细的考察.     

无胺法合成高硅丝光沸石的表征

采用XRD、SEM、FT-IR、MAS NMR等表征手段, 对以氟离子为结构导向剂无胺法合成的高硅丝光沸石进行了表征. 结果表明: 高硅丝光沸石结构属立方晶系, 晶胞参数小于传统低硅丝光沸石, 但b、c值要比相近硅铝比非氟体系合成的丝光沸石样品的大; 样品形貌及粒径与其硅铝比有关, 表明晶化条件对产物形貌及粒径均有影响; 随硅铝比的增大, FT-IR光谱中450、544、1053 cm-1谱带向高频移动, 720 cm-1谱带强度减弱, 表明骨架中铝减少而硅增多; 采用含氟无胺体系合成高硅丝光沸石时基本上不会产生非骨架铝.     

Synthesis and performance of electroless Ni–P–TiCN composite coatings on Al substrate

Electroless Ni–P and Ni–P–TiCN composite coatings have been deposited successfully on Al substrates. Scanning electron microscopy (SEM) and energy dispersive X‐ray (EDX) techniques were applied to study the surface morphology and the chemical composition of the deposited films. Moreover, X‐ray diffraction (XRD) proved that Ni–P and Ni–P–TiCN deposits have amorphous structures. The properties of Ni–P–TiCN/Al composite films such as hardness, corrosion resistance and electrocatalytic activity were examined and compared with that of Ni–P/Al film. The results of hardness measurements reveal that the presence of TiCN particles with Ni–P matrix improves its hardness. Additionally, the performance against corrosion was examined using Tafel lines and electrochemical impedance spectroscopy techniques in both of 0.6 M NaCl and a mixture of 0.5 M H₂SO₄ with 2 ppm HF solutions. The results indicate that the incorporation of high dispersed TiCN particles into Ni–P matrix led to a positive shift of the corrosion potential and an increase in the corrosion resistance for all aluminum substrates after their coating with Ni–P–TiCN. In addition, Ni–P–TiCN/Al electrodes showed a higher electrochemical catalytic activity and stability toward methanol oxidation in 0.5 M NaOH solution compared with that of Ni–P/Al. Copyright © 2014 John Wiley & Sons, Ltd.     

Improved pressure discharge property of surface modified Al/Bi2O3 composites

Al/Bi₂O₃ nanothermites were prepared via a self-assembly method using poly-4-vinylpyridine and surface modification of particles by a kind of binder oleic acid respectively. The structures, morphology, and energetic properties were characterized. The pressure discharge properties were studied by a closed bomb. The peak pressures and pressurization rates of Al/Bi₂O₃/P4VP and Al/Bi₂O₃/OA were 5590 kPa, 13.976 GPa s^–1 and 4858 kPa, 12.146 GPa s^–1, respectively, better than those of Al/Bi₂O₃ prepared by normal ultrasonic method (4559 kPa, 11.397 GPa s^–1 ). However, the decreased ignition delay time for self-assembled method and the increased one for modifying with oleic acid suggested different mechanism in accelerating the reaction of Al/Bi₂O₃. Moreover, the effect of mass fraction of oleic acid on nanothermite reaction was demonstrated.

     

In Situ X-Ray Absorption Spectroscopy Studies of Carbon Monoxide Oxidation in the Presence of Nanocomposite Cu–Fe–Al Oxide Catalysts

Kinetics and Catalysis - Nanocomposite Fe–Al and Cu–Fe–Al oxide catalysts are studied in the CO oxidation reaction. It is shown that the introduction of copper leads to a more...     

Effect of Fe2O3 as an accelerator on the reaction mechanism of Al–TiO2 nanothermite system

Thermite reactions between aluminum and metal oxides could lead to the formation of intermetallic matrix composites used in high-temperature industrial applications. Thermite reaction in Al–TiO₂ system needs a considerable amount of energy to take place by mechanochemical or by the combustion synthesis (CS) method due to the low amount of reaction enthalpy in Al–TiO₂ system. In this study, Fe₂O₃ was chosen as a accelerator for this system, to generate a high amount of heat which could be released between Fe₂O₃ and Al, leading to a more convenient reaction between Al and TiO₂ in the CS process. The results of XRD, SEM, and DSC analyses indicated that both the mechanical activation of Al–TiO₂ system in a high-energy ball mill and the Fe₂O₃ addition led to considerable effects of reduction in the reaction temperature and increase in the reaction intensity in Al–TiO₂ nanothermite system. Finally, it was shown that Fe₃Al intermetallic compounds as well as γ-AlTi and alumina phases in the final products were formed after the CS of the milled powders.     

Wet-Chemical Formation of Aluminophosphates

From refractory bonding, aluminophosphates are known to be hard and stable compounds. Porous AlPO₄ is widely studied, but little is known about compounds with a P/Al molar ratio higher than 1. Here we report on the formation of several aluminophosphates from acidic precursor solutions. We describe the reaction leading to the formation of Al(PO₃)₃ in more detail. Addition of HCl to the precursor solution leads to a monoclinic rather than the cubic phase of Al(PO₃)₃. Optimum formation temperature is 300–400°C, as at higher temperatures H₃PO₄ escapes before the reaction has been completed.     

Metal–organic framework of amine‐MIL‐53(Al) as active and reusable liquid‐phase reaction inductor for multicomponent condensation of Ugi‐type reactions

Metal–organic framework of NH₂‐MIL‐53(Al), with coordinative unsaturated aluminium sites, has been shown to be active in the Groebke–Blackburn–Bienaymé multicomponent coupling reaction based on Ugi‐type amine and aldehyde condensation over isocyanide and then a cyclization process. Interestingly this reaction occurred under solvent‐free conditions with high yield, in which the NH₂‐MIL‐53(Al) could be recovered and reused for five reaction cycles, giving a total turnover number of 455.     

Thermal and photocatalytic behavior of Ti/LDH nanocomposites

The development of nanocomposite photocatalyst based on layered double hydroxides (LDHs) associated with TiO₂ was the subject of this research. The thermally activated Zn–Al LDHs were selected as catalyst support precursor because of their proven photocatalytic activity and therefore their possible contribution to overall activity of novel Ti–Zn–Al nanocomposite. The catalyst precursor (Zn–Al LDH) was synthesized by low supersaturation coprecipitation method, and its association with active TiO₂ component targeting the formation of novel Ti–Zn–Al nanocomposite was achieved by wet impregnation. Simultaneous thermal analysis (TG–DTA) was used to investigate the thermal behavior of Zn–Al LDH and Ti–Zn–Al LDHs. Complementary, morphology, texture, and structure characterization was carried out. The photocatalytic test reaction was performed under UV light using the methylene blue degradation. The results confirmed a successful impregnation of TiO₂ on catalyst support precursor Zn–Al–LDH followed by considerable change in morphology and structure of Zn–Al LDH precursor. It was concluded that the synergic effect between TiO₂ and Zn–Al LDH precursor contributes to the overall photocatalytic activity.     

Interaction of Ca,P trace elements and Sr modification in AlSi5Cu1Mg alloys

Thermal and microscopy analyses were carried out to investigate the interaction of Sr modification with Ca and P trace elements in high-purity and commercial-purity Al–5Si–1Cu–Mg alloys. The results show how the addition of Sr to commercial-purity alloy induces significant changes in the nucleation and growth temperatures of eutectic Si since pre-eutectic Al₂Si₂(CaSr) intermetallics tend to poison AlP particles, making them inactive as nucleation sites for eutectic Si. In contrast, the addition of Sr to high-purity alloy shows no apparent influence on the characteristic temperatures of Al–Si eutectic reaction, even though the microstructural investigations reveal flake-to-fibrous transition in the eutectic Si structure. This indicates that the eutectic growth temperature, commonly used to predict eutectic modification level, is not a key feature of Sr modification, but it is indirectly caused due to the presence of additional impurities in commercial-purity alloys which affect the nucleation kinetics of eutectic Si.     

X-ray diffraction study of self-propagating high-temperature synthesis in the Zr–Al–C system

The phase formation process in the Zr–Al–C system during self-propagating high-temperature synthesis (SHS) has been studied by time resolved X-ray diffraction (TRXRD). The “nonuniqueness” of SHS routes in ternary solid-phase systems depending on synthesis initiation conditions has been established. No formation of ternary compounds belonging to the class of MAX phases has been observed in the considered system. It has been shown that the reaction responsible for the propagation of the combustion wave is the synthesis of ZrC, if SHS is initiated by a high-temperature pulse, and the end product also incorporates intermetallide zirconium phases. At the same time, the sequential formation of the Zr[Al] solid solution, the ZrAlC _х phase, and the intermetallide ZrAl₃, ZrAl₂, and Zr₂Al₃ phases occurs in the bulk ignition of the 2Zr–Al–C mixture under the conditions of great heat withdrawal during the reaction between an Al melt and Zr particles. No initiation of the Zr–C reaction takes place due to a low enthalpy of the reactions between aluminum and zirconium.     

ZnO/Mg–Al layered double hydroxides as strongly adsorptive photocatalysts

Nanocomposites of magnesium aluminium layered double hydroxides with carbonate anions (Mg–Al–CO₃-LDHs) and ZnO nanorods were prepared by a homogeneous precipitation process. The ZnO nanorods give the calcined Mg–Al–CO₃-LDHs, strong adsorbents of anionic dyes, photocatalytic activity. The nanocomposites were characterized by X-ray diffraction, transmission electron microscopy, and UV–vis diffuse reflectance spectroscopy. The photocatalytic activity of the nanocomposites was investigated by degradation of acid red G in aqueous solution, and the nanocomposite with the ZnO-to-Mg–Al–CO₃-LDHs mass ratio of 1:1 had the highest photocatalytic activity in this photocatalytic reaction.