新型负载配位催化剂ZBDPPEDAEPA／TiO2／Pd催化羰化反应研究

用乙二胺-N'-乙基膦酸的氨基与季盐[Ph2P+(CH2OH)2]Cl-,经曼尼希反应合成了N,N-双二苯膦甲基-乙二胺-N'-乙基膦酸(Ph2PCH2)2NCH2CH2N+H2CH2CH2PO3H-(BDPPEDAEPA), 并制备了相应的(N,N-双二苯膦甲基-乙二胺-N'-乙基膦酸-磷酸氢)锆载体Zr(HPO4)1.35[(Ph2PCH2)2NCH2CH2NHCH2CH2PO3]0.65·H2O (ZBDPPEDAEPA) 及二氧化钛和二氧化锆微粉表面包膜了ZBDPPEDAEPA的新型催化剂载体ZBDPPEDAEPA / TiO2、ZBDPPEDAEPA/ ZrO2和相应的钯催化剂ZBDPPEDAEPA / Pd、ZBDPPEDAEPA / TiO2 / Pd、ZBDPPEDAEPA/ZrO2/Pd. 在常压条件下, 对该类催化剂催化氯苄羰化反应的活性及产物组成作了初步考察. 对催化剂载体的粒径分析表明, ZBDPPEDAEPA / TiO2 / Pd的高活性归因于ZBDPPEDAEPA / TiO2载体的颗粒均匀、平均粒径小.ZBDPPEDAEPA以平均50 nm的薄层包膜在TiO2上, 这层包膜属于纳米级催化材料.     

新型晶态层状载体聚(苯乙烯-苯乙烯基膦酸)-磷酸锌轴向固载手性Salen Mn(Ⅲ)的合成及催化烯烃的环氧化性能

在温和条件合成了新型晶态层状有机聚合物-无机杂化载体材料聚(苯乙烯-苯乙烯基膦酸)-磷酸锌, 结合实验数据提出了其可能的理想结构模型. 对该载体进行氯甲基化和酚羟基化修饰后, 轴向配位固载手性Salen Mn(Ⅲ), 合成了一类新型的多相催化剂. 以间氯过氧苯甲酸为氧源, 考察了其对α-甲基苯乙烯及茚不对称环氧化反应的催化性能. 结果表明, 这类固载催化剂具有与均相Jacobsen催化剂相当或更高的催化活性和对映选择性, 并具有优良的重复使用性. 特别是在该氧化体系中, 当无助催化剂N-甲基吗啉氮氧化物(NMO)参与时, 固载催化剂获得更高的转化率及e.e.值, 这为其扩大化生产增加了可能性.     

链接基团对固载手性Salen Mn(m)催化不对称环氧化反应的影响

制备了二胺和二酚修饰的晶态有机聚合物-无机杂化载体低聚苯乙烯基膦酸-膦酸氢锆(LCZSPP)轴向固载手性Salen Mn(Ⅲ)催化剂,将其应用于非官能烯烃的多相不对称环氧化反应.研究了两类轴向连接基团及助催化剂在催化不对称环氧化反应中的影响.结果表明,通过二胺为链接基团固载的催化剂在加入轴向助剂(NMO)的情况下,转化...     

辅以时滞的pH-敏感介孔膦酸锆对双氯芬酸钠的可控结肠靶向释放

以pH-敏感介孔膦酸锆作为药物载体, 选用治疗时辰节律性疾病(风湿性关节炎)的药物双氯芬酸钠作为药物模型, 利用蘸涂的方法对载药的pH-敏感介孔膦酸锆进行时滞膜的包覆, 建立起一个时滞型和pH-敏感型相结合的口服结肠靶向给药系统. 在系统研究pH-敏感介孔膦酸锆对双氯芬酸钠吸附和释放的基础之上, 通过调控时滞膜的厚度控制释放双氯芬酸钠的时滞时间约为6 h. 该给药系统在人工模拟胃液中3 h内完全不释放双氯芬酸钠, 而在人工模拟肠液中最初的3 h(可以看成发生在小肠)所释放的双氯芬酸钠仅为全部释放量的9%, 在之后的46 h内(可以看成发生在结肠)缓慢释放的双氯芬酸钠则占全部释放量的90%以上. 这样, pH-敏感介孔膦酸锆作为新型药物载体与时滞效应相结合, 通过时滞和pH-敏感双重控制实现了治疗时辰节律性疾病药物在结肠的定位释放.     

含膦,氮配体的混合膦酸锆—钯催化剂的研制

用氯化二苯基膦为膦化试剂,首次对多乙烯多胺乙基膦酸－磷酸氢锆Ｚｒ（ＨＰＯ４）１．３５（Ｏ２ＰＣＨ２ＣＨ２（ＮＨＣＨ２ＣＨ２）ｍＮＨ２）０．６５·Ｈ２Ｏ（ＺＰ－ＰＥＰＡＥＰＡ,ｎ＝０,１,２,３,４）载体表面进行二苯基膦化,合成了一类含膦氮配体的新型混合膦酸锆载体及负载钯催化剂。研究了有机膦酸侧链不同链长和Ｐｈ２ＰＣｌ用量对配体载体制备的影响,并用ＩＲ,ＴＧ,ＤＴＧ,ＤＴＡ对这类载体及催化剂进行表征     

含锆、钙熔铁型氨合成催化剂的Mssbauer谱

研究了含锆和含锆、钙的熔铁型氨合成催化剂的M ssbauer谱。结果表明 ,Zr4 +进入Fe3O4 晶格使B位扩张 ,促进了Fe3O4 的还原与Al的均匀分布。含锆、钙催化剂由于锆、钙的作用使Zr4 +进入晶格减少 ,还原更易在A位发生 ,这些情况在水冷成形的球形催化剂中更为明显     

碳纳米材料及其在多相催化中的应用

碳纳米材料（包括零维、一维、二维碳纳米材料以及碳纳米孔材料）是一类新型的催化剂或催化剂载体材料,在氧化脱氢、选择加氢、合成氨、氨分解制氢以及燃料电池等多相催化领域具有广阔的应用前景。本文综述了近年来新型碳纳米材料在多相催化领域中的应用研究进展,介绍了这类催化材料的制备方法,重点阐述了碳载体的微/介观结构、掺杂、电子性质、表面性质、限域效应等对所担载的催化活性组分的分散,对反应物的扩散以及对催化反应的活性和选择性等方面的影响。     

新型烷氧基修饰的手性SalenMn（Ⅲ）固载催化剂的合成及其在非功能化烯烃不对称环氧化反应中的应用

合成了一系列以有机聚合物-无机杂化材料聚（苯乙烯-苯乙烯基膦酸）-磷酸氢锆（ZPS-PVPA）为载体,烷氧基为连接基团的新型固载手性Salen Mn（III）催化剂,并运用FT-IR,UV-vis,XPS,SEM,TG,元素分析等手段对其进行了表征.以m-CPBA为氧化剂,茚和α-甲基苯乙烯为底物,考察了催化剂对非功能...     

手性salen Mn(Ⅲ)的制备及其对α-甲基苯乙烯不对称环氧化反应的催化

本文以聚（苯乙烯-异丙烯膦酸）-磷酸氢锆（ZPS-IPPA）为载体,对该载体进行氯甲基化、胺化修饰后与手性Salen Mn(Ⅲ)轴向配位,合成了一种新的固载型手性Salen Mn(Ⅲ)催化剂,采用FTIR,DR UV-Vis,XPS,SEM,TEM,TG等手段对催化剂进行表征．以次氯酸钠和间氯过氧苯甲酸为氧化剂,考察了固载催化剂对ａ-甲基苯乙烯不对称环氧化反应的催化性能,结果表明,固载型催化剂的催化活性比相应均相催化剂略低,但对映体选择性明显提高．在NaClO/PPNO氧化剂体系中0 ℃反应24h,ａ-甲基苯乙烯环氧化物的转化率达68%,e.e.值达99%．循环使用8次后催化效果无明显降低．     

膦化聚苯乙烯担载四核羰基钴簇的合成和催化作用

合成了两种含膦聚苯乙烯载体和此二载体与四核羰基钴簇CO_4(CO)_8(μ_2-CO_2(μ_4-PPh)_2通过配体交换反应,合成两种担载的金属原子簇催化剂.用IR、VU-DRS和XPS表征担载簇配合物的结构.考察了担载簇催化剂对讣茑烯烃的氢甲酰化反应的催化活性.其活性顺序为:1-庚烯>环己烯>二异丁烯>2-辛烯>苯乙烯.     

Highly efficient and green oxidation of alkanes and alkylaromatics with hydrogen peroxide catalysed by silver and vanadyl on mesoporous silica‐coated magnetite

A heterogeneous catalyst (FeSi/Ag/VO) based on silver and vanadyl as active sites and mesoporous silica‐coated nanospheres of magnetite (Fe₃O₄@m‐SiO₂) as support was successfully prepared by deposition of Ag nanoparticles and the covalent grafting of vanadyl(IV) acetylacetonate on Fe₃O₄@m‐SiO₂. The catalyst exhibited excellent activity for the oxidation of alkanes, benzene and alkylaromatics using green oxidant H₂O₂ and oxalic acid in acetonitrile at 60 °C.     

Pd-Cu-Clx/Al2O3催化剂对CO氧化的稳定性

CO催化氧化广泛应用于空气净化、机动车尾气治理和CO气体传感器中.在CO氧化催化剂设计与制备过程中,催化剂与使用环境密切相关.例如工业和机动车尾气净化需要在高温(200–600°C)下进行,而对于半密闭空间(隧道或者地下停车场)空气净化需要在室温和高相对湿度下进行.频繁冷启动导致半密闭空间CO浓度累积而超过排放控制标准,因此制备室温、高相对湿度下CO氧化催化剂是面临的重要问题之一.负载型Wacker催化剂对于CO低温催化氧化的研究一直受到广泛关注.环境中少量水的存在会促进负载型Wacker催化剂对CO的低温氧化性能,但随着水沉积量的增加,活性位点将被覆盖,并且Pd和Cu活性组分之间的紧密结构被破坏,从而导致催化剂的失活,即催化剂的稳定性变差.因此,为了提高催化剂在高相对湿度下的稳定性,利用二乙氧基二甲基硅烷对Al2O3载体进行硅烷化处理,以增加载体的疏水性,考察载体疏水改性对CO低温氧化过程中催化剂稳定性的影响.催化剂的稳定性测试结果表明,在0°C,100%相对湿度条件下,未改性催化剂在约20 h内CO转化率由81%下降到50%;载体硅烷化后制备的催化剂在反应进行150 h后,CO转化率仍保持在78%,即反应活性未见降低.由此表明催化剂载体经有机硅烷改性后,可显著增强催化剂在低温、高相对湿度下的稳定性.N2吸附/脱附和水吸附实验结果表明,载体硅烷化改性并未对催化剂的比表面积产生影响,但显著降低了催化剂上水沉积速度和沉积量,未改性催化剂的初始吸水速度是改性后催化剂的4倍,但改性后催化剂的饱和吸水率仅占未改性催化剂的1/3.X射线衍射结果表明,载体预处理后活性物种Cu2(OH)3Cl晶粒尺寸有所增加.氢气程序升温还原、X射线光电子能谱结果表明,载体硅烷化预处理改善了催化剂中Cu和Pd物种的化学分布及接触状态,增加了与Pd物种紧密接触的Cu物种的量,从而促进了Cu物种的还原.与此同时,载体硅烷化显著降低了催化剂表面Cl离子的浓度,从而影响到对CO吸附.为了进一步研究水与催化剂稳定性之间的关系,采用原位红外漫反射(In situ DRIFT)对催化剂进行表征.负载型Wacker催化剂对CO氧化反应机理为:Pd是CO氧化反应的活性中心,通过Pd和Cu物种之间的氧化还原循环来实现CO氧化,且Pd+比Pd2+具有更高的CO氧化性能.反应气氛中水的存在,有利于CO在Pd+上氧化、以及金属态Pd被Cu2+物种再氧化的过程,同时水也显著促进了催化剂表面碳酸盐的生成以及抑制了活性物种Pd+生成.与表面碳酸盐累积相比,水对于活性物种Pd+生成的抑制作用是导致催化剂活性降低的主要原因.     

Platinum-Iron(II) Oxide Sites Directly Responsible for Preferential Carbon Monoxide Oxidation at Ambient Temperature: An Operando X-ray Absorption Spectroscopy Study**

Operando X-ray absorption spectroscopy identified that the concentration of Fe²⁺ species in the working state-of-the-art Pt−FeO_x catalysts quantitatively correlates to their preferential carbon monoxide oxidation steady-state reaction rate at ambient temperature. Deactivation of such catalysts with time on stream originates from irreversible oxidation of active Fe²⁺ sites. The active Fe²⁺ species are presumably Fe⁺²O⁻² clusters in contact with platinum nanoparticles; they coexist with spectator trivalent oxidic iron (Fe³⁺) and metallic iron (Fe⁰) partially alloyed with platinum. The concentration of active sites and, therefore, the catalyst activity strongly depends on the pretreatment conditions. Fe²⁺ is the resting state of the active sites in the preferential carbon monoxide oxidation cycle.     

CuII@PAA/PVC mesoporous fibers: A hybrid wedding as a high-performance versatile heterogeneous catalyst for A3, KA2, and decarboxylative A3 reactions

Efforts made on the development of a novel, simple, cost-effective, and efficient approach to fabricate a copper catalyst immobilized on mesoporous poly (acrylic acid)/poly (vinyl chloride) hybrid fibers (Cu^II@PAA/PVC) for versatile catalytic applications in A₃, KA₂, and decarboxylative A₃ couplings has been described in this present work. The characterization of the mesoporous hybrid fibers was well performed by BET, FTIR, SEM, EDX, XPS, and TGA techniques. The pore structure and surface area were calculated by using BET measurement analysis. The obtained mesoporous Cu^II@PAA/PVC fibers exert high catalytic performance in the synthesis of propargylamines via one-pot A₃, KA₂, and decarboxylative A₃ reactions over a series of substrates without employing expensive ligands or inert atmosphere. The active Cu²⁺ species chelating with carboxylate groups in PAA/PVC hybrid fibers plays a key role in the catalysis. Meanwhile, the unique mesoporous structure and fiber morphology facilitate a better mass transfer and enlarge its contact area with substrates in the course of a reaction. Moreover, the Cu²⁺–carboxylate chelation could suppress the leaching of active Cu²⁺ species from the catalyst and thus lead to the catalyst has excellent performance and good durability as well as reusability.     

Etude par effet Mössbauer des composés de type “bronzes fluorés” MxFeF3 (M = K,Rb, Cs,NH4)

The hexagonal, tetragonal and pyrochlore-type nonstoichiometric iron fluorides M_xFeF₃ (M = K, Rb, Cs, NH₄) have been studied by Mössbauer spectroscopy over the temperature range 4.2 to 295 K. The magnetic transition temperatures have been determined. The ferrous and ferric ions remain in discrete oxidation states indicating the absence of charge hopping. The broadened lines of the spectra of the hexagonal and tetragonal phases are consistent with the disordering of Fe²⁺ and Fe³⁺ in the structure. By contrast, the narrow linewidths of the spectra of the pyrochlore-type phases characterize a structural ordering between the ferrous and ferric ions.     

Revealing the Effect of Surface Composition on Multiwalled Carbon Nanotubes Supported Pt-Fe Alloy Electrocatalysts for Methanol Oxidation Performance

The designs of efficient and inexpensive Pt-based catalysts for methanol oxidation reaction (MOR) are essential to boost the commercialization of direct methanol fuel cells. Here, the highly catalytic performance PtFe alloys supported on multiwalled carbon nanotubes (MWCNTs) decorating nitrogen-doped carbon (NC) have been successfully prepared via co-engineering of the surface composition and electronic structure. The Pt₁Fe₃@NC/MWCNTs catalyst with moderate Fe³⁺ feeding content (0.86 mA/mg_Pt) exhibits 2.26-fold enhancement in MOR mass activity compared to pristine Pt/C catalyst (0.38 mA/mg_Pt). Furthermore, the CO oxidation initial potential of Pt₁Fe₃@NC/MWCNTs catalyst is lower relative to Pt/C catalyst (0.71 V and 0.80 V). Benefited from the optimal surface compositions, the anti-corrosion ability of MWCNT, strong electron interaction between PtFe alloys and MWCNTs and the N-doped carbon (NC) layer, the Pt₁Fe₃@NC/MWCNTs catalyst presents an improved MOR performance and anti-CO poisoning ability. This study would open up new perspective for designing efficient electrocatalysts for the DMFCs field.     

Simple Preparation and Application of TEMPO‐Coated Fe3O4 Superparamagnetic Nanoparticles for Selective Oxidation of Alcohols

The organic oxidant TEMPO (2,2,4,4‐tetramethylpiperdine‐1‐oxyl) was immobilized on iron oxide (Fe₃O₄) superparamagnetic nanoparticles by employing strong metal‐oxide chelating phosphonates and azide/alkyne “click” chemistry. This simple preparation yields recyclable TEMPO‐coated nanoparticles with good TEMPO loadings. They have excellent magnetic response and efficiently catalyze the oxidation of a wide range of primary and secondary alcohols to aldehydes, ketones, and lactones under either aerobic acidic Mn^II/Cu^II oxidizing Minisci conditions, or basic NaOCl Anelli conditions. The nanoparticles could be recycled more than 20 times under the Minisci conditions and up to eight times under the Anelli conditions with good to excellent substrate conversions and product selectivities. Immobilization of the catalyst through a phosphonate linkage allows the particles to withstand acidic oxidizing environments with minimal catalyst leaching. Clicking TEMPO to the phosphonate prior to phosphonate immobilization, rather than after, ensures the clicked catalyst is the only species on the particle surface. This facilitates quantification of the catalyst loading. The stability of the phosphonate linker and simplicity of this catalyst immobilization method make this an attractive approach for tethering catalysts to oxide supports, creating magnetically separable catalysts that can be used under neutral or acidic conditions.     

Investigation of multiplet splitting of Fe 2p XPS spectra and bonding in iron compounds

Ferrous (Fe²⁺) and ferric (Fe³⁺) compounds were investigated by XPS to determine the usefulness of calculated multiplet peaks to fit high‐resolution iron 2p_3/2 spectra from high‐spin compounds. The multiplets were found to fit most spectra well, particularly when contributions attributed to surface peaks and shake‐up satellites were included. This information was useful for fitting of the complex Fe 2p_3/2 spectra for Fe₃O₄ where both Fe²⁺ and Fe³⁺ species are present. It was found that as the ionic bond character of the iron —ligand bond increased, the binding energy associated with either the ferrous or ferric 2p_3/2 photoelectron peak also increased. This was determined to be due to the decrease in shielding of the iron cation by the more increasingly electronegative ligands. It was also observed that the difference in energy between a high‐spin iron 2p_3/2 peak and its corresponding shake‐up satellite peak increased as the electronegativity of the ligand increased. The extrinsic loss spectra for ion oxides are also reported; these are as characteristic of each species as are the photoelectron peaks. Copyright © 2004 John Wiley & Sons, Ltd.     

Highly dispersed Cu supported on mesoporous Al-KIT-6 for oxidative carbonylation of methanol to dimethyl carbonate

Microporous NaY zeolite is a common support of Cu catalysts for oxidative carbonylation of methanol, but the dispersion of Cu species on NaY is usually subjected to its micropore size. Here, ordered mesoporous KIT-6 was employed as the support for Cu catalyst and Al was incorporated into its framework to increase the surface acidity, which eventually improves the surface exchange capacity and Cu dispersion. The evolution of the state of Cu species on KIT-6 was analyzed combined with control of Cu loading. The physicochemical properties of the supports and corresponding catalysts were characterized by N₂ adsorption–desorption, X-ray diffraction, ammonia temperature programmed desorption, Fourier transform infrared spectra, transmission electron microscopy, hydrogen temperature programmed reduction, and X-ray photoelectron spectroscopy. It was found that mesoporous KIT-6 showed better Cu dispersion than microporous NaY zeolite. Agglomerated CuO, dispersed CuO, and Cu²⁺ are the major Cu species observed on the catalyst surface. The increased surface acidic sites of KIT-6 by Al incorporation promoted the formation of Cu²⁺ and dispersion of CuO. With the increase in Cu loading, the Cu²⁺ content in the catalyst was decreased gradually along with increase in the bulk CuO. It was speculated that some exchanged Cu²⁺ could be transformed into highly dispersed CuO and even bulk CuO after calcination at a high Cu loading. Combined with the catalyst evaluation results, it was deduced that highly dispersed Cu²⁺ and CuO particles play significant roles in catalytic activity. The catalyst Cu/Al-K-10 achieved the highest space time yield of dimethyl carbonate of 135.4 mg/(g·h), which is 2.7 times the Cu/K-10 owing to its more dispersed Cu species. This laid the basis for preparing highly dispersed Cu species on mesoporous silica supports.     

Fe–Co/sulfonated polystyrene as an efficient and selective catalyst in heterogeneous Baeyer–Villiger oxidation reaction of cyclic ketones

A highly efficient catalyst Fe–Co/sulfonated polystyrene (Fe–Co/SPS) was introduced and synthesized, which catalyzed BV oxidation of ketones with aqueous hydrogen peroxide to give the corresponding lactones in high yield and selectivity. Solid acid catalyst of Fe–Co/SPS has been prepared by using the 98-wt% sulfuric acid as the sulfonating agent and CoCl₂ combined FeCl₃ as sources of metal ions. Various physical–chemical characterizations including FT-IR, XRD, SEM and TGA, revealed that bimetallic ions Fe³⁺–Co²⁺ species in the sulfonated polystyrene framework were responsible for the catalytic activities. The BV reaction catalyzed by Fe–Co/SPS highlighted the special effects between metal ions and protonic acids as well as solvent-free heterogeneous catalytic oxidation with excellent conversion.