层状无机化合物--磷酸锆的研究和应用进展

简要概述层状无机化合物的物理和化学性质,以及层状磷酸锆的结构特点和性质,对近年来层状磷酸锆在光、电、催化、分子识别等领域的研究和应用进行了综述,并展望了层状磷酸锆的研究前景.     

Dealloying of Mesoporous PtCu Alloy Film for the Synthesis of Mesoporous Pt Films with High Electrocatalytic Activity

Mesoporous Pt film with highly electrocatalytic activity is successfully synthesized by dealloying of mesoporous PtCu alloy film prepared through electrochemical micelle assembly. The resulting mesoporous electrode exhibits high current density and superior stability toward the methanol oxidation reaction.     

层状磷酸锆的合成与性质研究

用回流、水热晶化和HF沉淀三种方法制备了α－Zr(HPO₄)₂·H₂O(α－ZrP)晶体.HF沉淀法制备的α－ZrP晶体尺寸最大,层板有序度最高,水热法次之,回流法最差.水热法合成的α－ZrP尾板本身的结晶度最高.随α－ZrP晶粒增大,层板有序度和层间水的脱除温度均提高,并且需要嵌入更多的烷基胺和醇胺才能导致层板胶体化.HF沉淀法和回流法制备的α－ZrP层板较易水解,水热法制备的样品水解率较低,但三种样品在有机胺浓度为等当点时水解率均不超过20％.     

磷酸锆及其衍生物的离子交换性能*

α-磷酸锆（α-Zr(HPO₄)₂·H₂O, α-ZrP）、γ-磷酸锆（Zr(PO₄)(H₂PO₄)·2H₂O,缩写为γ-ZrP）及其衍生物由于在离子交换、质子传导、插层化学、催化、光化学、材料化学等领域有潜在的应用前景,因而引发了大量的研究工作。本文综述了碱金属、碱土金属、过渡金属离子等与磷酸锆及其衍生物的离子交换反应机理、热力学和动力学特性,另外也讨论了发光金属配合物与磷酸锆的离子交换反应研究进展。     

无机纳米与多孔材料合成中的凝聚态化学

所谓凝聚态,一般意义上是指液态和固态,而凝聚态化学,即是在固相和液相中的各种化学过程。在无机材料,特别是无机纳米与多孔材料的合成制备中,凝聚态化学过程贯穿其中,几乎无处不在。在固相材料合成过程中,通过液相中的各种化学反应以获得目标固体材料的所需组分和物相,也许就是无机材料合成中一个最基本的凝聚态化学问题;而多孔如微孔或介孔材料合成中,更涉及伴随组分和物相形成过程中的孔结构形成与调控;进一步,在制备面向实际应用如催化剂和药物载体时,则在以上的各项要求之外,还必须考虑材料的表面活性位、缺陷等关键因素,以及颗粒尺寸、分散性和形貌等几何和物理特性。本文以无机氧化物为对象,讨论了无机材料在凝聚态化学合成过程中的几个侧面,包括纳米颗粒和粉体的化学合成方法,多孔材料的合成和多孔复相结构的合成调控,以及多级孔结构沸石的合成制备与催化性能,以期能加深对材料合成中凝聚态化学过程的认识,并期待以凝聚态化学为指导,进一步推动无机材料特别是纳米多孔材料合成的发展。     

Highly Stable Mesoporous Zirconium Porphyrinic Frameworks with Distinct Flexibility

The construction of highly stable metal–porphyrinic frameworks (MPFs) is appealing as these materials offer great opportunities for applications in artificial light‐harvesting systems, gas storage, heterogeneous catalysis, etc. Herein, we report the synthesis of a novel mesoporous metal–porphyrinic framework (denoted as NUPF‐1) and its catalytic properties. NUPF‐1 is constructed from a new porphyrin linker and a Zr₆O₈ structural building unit, possessing an unprecedented doubly interpenetrating scu net. The structure exhibits not only remarkable chemical and thermal stabilities, but also a distinct structural flexibility, which is seldom seen in metal–organic framework (MOF) materials. By the merit of high chemical stability, NUPF‐1 could be easily post‐metallized with [Ru₃(CO)₁₂], and the resulting {NUPF‐1–RuCO} is catalytically active as a heterogeneous catalyst for intermolecular C(sp³)?H amination. Excellent yields and good recyclability for amination of small substrates with various organic azides have been achieved.     

Formation of Diverse Mesophases Templated by a Diprotic Anionic Surfactant

The synthesis system for mesophase formation, using the diprotic anionic surfactant N‐myristoyl‐L ‐glutamic acid (C₁₄GluA) as the structure‐directing agent (SDA) and N‐trimethoxylsilylpropyl‐N,N,N‐trimethylammonium chloride (TMAPS) as the co‐structure‐directing agent (CSDA), has been investigated and a full‐scaled synthesis‐field diagram is presented. In this system we have obtained mesophases including three‐dimensional (3D) micellar cubic Fm m, Pm n, Fd m, micellar tetragonal P4₂/mnm, two‐dimensional (2D) hexagonal p6mm and bicontinuous cubic Pn m, by varying the C₁₄GluA/NaOH/TMAPS composition ratios. From the diagram it can be concluded that the mesophase formation is affected to a high degree by the organic/inorganic‐interface curvature and the mesocage–mesocage electrostatic interaction. Bicontinuous cubic and 2D‐hexagonal phases were found in the low organic/inorganic‐interface curvature zones, whereas micellar cubic and tetragonal mesophases were found in the high organic/inorganic‐interface curvature zones. Formation of cubic Fm m and tetragonal P4₂/mnm was favoured in highly alkaline zones with strong mesocage–mesocage interactions, and formation of cubic Pm n and Fd m was favoured with moderate mesocage–mesocage interactions in the less alkaline zones of the diagram.     

以1,6-己二胺为模板剂的层状磷酸锆晶体的合成与表征

 采用水热法合成了以1,6-己二胺(HDA)为模板剂的层状磷酸锆晶体0.5·1.5H2O,并用单晶及粉末XRD,IR和TG-DTA等对其结构和性质进行了表征. 该晶体是由磷酸锆无机层、有机胺以及水分子三部分构成的层状结构,层间距约为1.77 nm,无机层结构为γ-型. 位于有机胺两端的氮与无机层表面部分羟基的氧以氢键连接,水分子占据磷酸锆层间的两种位置. 单晶结构模拟得到的XRD谱与从粉末样品采集的XRD谱基本吻合. 此晶体在180 ℃下脱去水分子,在220 ℃下加热3 h其结构未发生明显变化; 有机胺模板剂在250 ℃下开始分解.     

Tailoring the Structure of Hierarchically Porous Zeolite Beta through Modified Orientated Attachment Growth in a Dry Gel System

The crystallization of zeolite beta in a dry gel system is found to follow the orientated attachment growth route, escorted with a temporal morphology change from bulky gel, through aggregation of the particulate to large zeolitic crystals. Modification of the precrystallized gel with organosilanes can be used to tune the morphology of the ultimate beta. When hexadecyltrimethoxysilane (HTS) is employed to modify precrystallized gel, a resumed secondary growth produces a hybrid mesocrystal of agglomerated nanozeolites. Combustive removal of organics leads to the formation of hierarchically porous zeolite beta of 100 to 160 nm, composed of nanocrystal building units ranging from 20 to 40 nm, with a noticeable micropore volume of 0.19 mL g^?1 and a meso/macropore size between 5 and 80 nm. Conversely, when 1,8‐bis(triethoxysilyl)octane (BTO) is utilized to modify the same precrystallized gel, assemblages of discrete beta nanozeolite of around 35 nm are generated. These assemblages construct a hierarchical zeolite beta with a micropore volume of 0.20 mL g^?1 and auxiliary pores ranging from 5 to 100 nm. Both organosilanes bring about well‐connected hierarchical pore networks. HTS has little effect on the Brønsted/Lewis acidity, whereas BTO causes a substantial reduction of strong Brønsted acid sites. The hierarchical beta zeolite‐supported Pt catalyst exhibits improved catalytic performance for the hydroisomerization of n‐heptane.     

高含锆量的中孔分子筛Zr-MSU-V的合成与表征

以十二烷二胺(DADD)为模板剂,通过优化反应体系和合成条件,制备出了一种具有高锆含量的中孔分子筛Zr-MSU-V,采用XRD,IR,BET,TG-DTA,UV-V is和TEM等手段对分子筛进行表征.考察了S i∶Zr、合成温度对分子筛结构的影响.结果表明,高锆含量的Zr-MSU-V仍能保持良好的层状结构;温度对分子筛中孔结构的形成具有显著的影响.     

Controlling the BET Surface Area of Porous Carbon by Using the Cd/C Ratio of a Cd–MOF Precursor and Enhancing the Capacitance by Activation with KOH

Herein, four new cadmium metal–organic frameworks (Cd–MOFs), [Cd(bib)(bdc)]_∞ ( 1 ), [Cd(bbib)(bdc)(H₂O)]_∞ ( 2 ), [Cd(bibp)(bdc)]_∞ ( 3 ), and [Cd₂(bbibp)₂(bdc)₂(H₂O)]_∞ ( 4 ), have been constructed from the reaction of Cd(NO₃)₂ ? 4 H₂O with 1,4‐benzenedicarboxylate (H₂bdc) and structure‐related bis(imidazole) ligands (1,4‐bis(imidazol‐1‐yl)benzene (bib), 1,4‐bis(benzoimidazol‐1‐yl)benzene (bbib), 4,4′‐bis(imidazol‐1‐yl)biphenyl (bibp), and 4,4′‐bis(benzoimidazol‐1‐yl)biphenyl (bbibp)) under solvothermal conditions. Cd–MOF 1 shows a 2D (4,4) lattice with parallel interpenetration, whereas 2 displays an interesting 3D interpenetrating dia network, 3 exhibits an unusual 3D interpenetrating dmp network, and 4 presents a 3D self‐catenated pillar‐layered framework with a Schäfli symbol of [4³ ? 6³]₂ ? [4⁶ ? 6¹⁶ ? 8⁶]. The structural diversity indicates that the backbone of the bis(imidazole) ligand (including the terminal group and spacer) plays a crucial role in the assembly of mixed‐ligand frameworks. By using the pore‐forming effect of cadmium vapor, for the first time we have utilized these Cd–MOFs as precursors to further prepare porous carbon materials (PCs) in a calcination–thermolysis procedure. These PCs show different porous features that correspond to the topological structures of Cd–MOFs. Significantly, it was found that the specific surface area and capacitance of PCs are tuned by the Cd/C ratio of the MOF. Furthermore, the as‐synthesized PCs were processed with KOH to obtain activated porous carbon materials (APCs) with higher specific surface area and porosity, which greatly promoted the energy‐storage capacity. After full characterization, we found that APC‐bib displays the largest specific surface area (1290 m² g^?1) and total pore volume (1.37 cm³ g^?1) of this series of carbon materials. Consequently, APC‐bib demonstrates the highest specific capacitance of 164 F g^?1 at a current density of 0.5 A g^?1, and also excellent retention of capacitance (≈89.4 % after 5000 cycles at 1 A g^?1). Therefore, APC‐bib has great potential as the electrode material in a supercapacitor.     

高比表面积蠕虫状介孔SnO2的合成与表征

 以聚乙二醇 (PEG) 为模板剂, 氯化锡为锡源, 尿素为沉淀剂, 采用水热法合成出高比表面积的蠕虫状介孔四方相金红石型 SnO2. 考察了 PEG 分子量及其浓度、水热温度和焙烧温度对 SnO2 孔结构和形貌的影响. 采用 X 射线衍射、N2 吸附-脱附、透射电镜、红外光谱和紫外-可见光谱等技术对样品进行了表征. 结果表明, 模板剂可被水洗除去, PEG 分子量对介孔 SnO2 的比表面积影响不大, 而 PEG 浓度、水热温度和焙烧温度的影响较大. 在以分子量为 6000 的 PEG 与 Sn 的摩尔比为 0.01 的条件下, 于 120 oC 水热处理 29 h 后可合成出比表面积高达 161 m2/g 和平均孔径为 2.6 nm 的蠕虫状介孔 SnO2. 所制得样品具有较好的紫外光吸收性能, 适宜用作催化剂、载体和气体传感器等.