Untersuchungen an katalytisch aktiven Oberflächenverbindungen. II. Zur Existenz unterschiedlicher Vanadium(V)-oxid-Oberflächenphasen auf SiO2 und ihre katalytischen Eigenschaften

Studies on Catalytically Active Surface Compounds. II. On the Existence of Different Vanadium(V) Oxide Surface Phases on SiO₂ and their Catalytic Properties In dependence on the SiOH concentration of the Aerosil surface two different disperse vanadium(V) oxide phases are obtained, which differ characteristically in their reflexion spectra, their chemisorption behaviour towards butene and their catalytic properties in the oxidation of butene and ethanol. At high values of the original concentration of SiOH groups a δ″ phase is formed which gives after desorption of adsorbed water at 250°C, a reflexion spectrum that points at a tetrahedral coordination of the V^v; this phase shows a relative low activity for both reactions. At a lower original concentration of SiOH a δ″ phase of the vanadium(V) oxide is formed, the reflexion spectrum of which, points at an octahedrally coordinated vanadium(V) oxide. This phase is considerably more active than the former.     

Structure of surface compounds formed during chemisorption of BBr3 on dehydrated Aerosil

The chemisorption of boron bromide on the surface of Aerosil calcined at 870 K in vacuo was studied by IR spectroscopy combined with chemical and gravimetric analysis. It was determined that the chemical reaction of structural silanol groups with BBr₃ vapor occurs monofunctionally with the formation of SiOBBr₂ groups. This indicates uniform distribution of isolated silanol groups on the surface of dehydrated Aerosils.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 25, No. 3, pp. 374–377, May–June, 1989.     

Deactivation of silica surfaces with a silanol-terminated polysiloxane; structural sharacterization by inverse gas chromatography and solid-state NMR

Retention gape deactivated with Silicone OV-1701-OH show good chromatographic performance and remarkable stability against water induced stationary phase degradrdation. In an attempt to better understand the findamentals off the deactivation process using silanol terminated polysiloxanes, a fumed silica was deactivated with Silicon OV-1701-OH. In contrast to fused silic capillaries, fumed silica (Aerosil A-200) can be studied by ²⁹Si cross-polarization magic-angle-spinning (CPMAS) NMR, thus serving as a model substrate for fused silica. Retention data from inverse gas chromatography at infinite dilurion and ²⁹Si CP MAS NMR data of five Aerosil phases, differing in residual silanol surface concentration, are correlated with the aim of validating this approach for stationary phase characterization. A comparatively detailed model of the deactivating polymer layer that explains the observed absorption activities is deduced. Surface silanols are shown to play a key role in the polymer layer, the structure of which is of primary importance for the absorption behavior after deactivation. Contrary to common belief, the absolute silanol surface concentration after deativation is only of secondary importance for the overall absorption activity. High silanol surface concentrations enhance degradation of the polysiloxane chains into small cyclic fragments as well as subsequent absorption and immobolization to the silica substrate surface. The mobility of linear polysiloxane chains in the kHz regime (as determined bby NMR cross-polarization dynamics) appears to determine the extent which the residual silanols are accessible for analytes. It is therefore anticipated that there is an optimum silanol surface concentration of fused silica surfaces to be deactivated with silanol terminated polysiloxanes; it should be lazrge enough to adsord polymer fragments, but not large to avoid excessive residual silanol activity.     

Über die Chemie der Oberfläche des Titandioxids. III. Reaktionen der basischen Hydroxylgruppen auf der Oberfläche

Adsorption of various acids on anatase of high surface area was studied. Phosphoric, arsenic, sulphuric and acetic acid are specifically adsorbed; hydrochloric and perchloric acid are not adsorbed. Phosphate ions are bound on the TiO₂ surface also from NaH₂PO₄ and Na₂HPO₄ solutions; sodium ions are adsorbed at the same time. OH^? ions on the surface are replaced by anions such as H₂PO in these reactions. The bonding of adsorbed phosphate ions is not purely ionic. Infrared spectra show that adsorbed acetic acid is bound as acetate. NO₂ reacts with the basic OH^? ions undergoing disproportionation; OH^? ions are replaced by NO ions. Phophoric acid adsorption corresponded always to half the total OH population on five different TiO₂ samples. The TiO₂ surface is not completely covered by OH groups. The maximum coverage is ca. 7.5 μMol OH/m².     

Ethylene polymerization with a supported vanadium catalyst obtained by the molecular deposition method

An active-phase monolayer has been deposited on SiO₂ using replacement of the surface OH groups by VOCl₃ vapour. The amount of vanadium fixed on the SiO₂ surface depends on the initial concentration of the silanol groups and ranges from 3.36 to 1.43%. In combination with diethyl aluminium chloride, the products are active catalysts for ethylene polymerization. The effects of the reaction conditions (the time of catalyst-complex formation, the catalyst life time and the temperature of polymerization) as well as the effect of the vanadium content, the A1:V ratio and the presence of diphenyl magnesium on the activity of the catalyst system have been investigated. The catalyst activity was found to depend strongly on the amount of vanadium fixed on the support surface. The maximum productivity obtained is about 22,000 gPE/g vanadium. Some basic characteristics of the synthesized polymer such as tensile strength, elongation at break, density and crystallization degree are given.     

Catalysis of hydrosilylation by well-defined rhodium siloxide complexes immobilized on silica

Rhodium surface siloxide complexes were prepared directly by condensation of the molecular precursors ([{Rh(μ-OSiMe₃)(cod)}₂], [{Rh(μ-OSiMe₃)(tfb)}₂], [{Rh(μ-OSiMe₃)(nbd)}₂]) with silanol groups on silica surface (Aerosil 200 and SBA-15) and their structures were characterized by ¹³C and ²⁹Si CP/MAS NMR spectroscopy. Such single-site complexes were tested for their activity in hydrosilylation of carbon–carbon double bonds with triethoxysilane, heptamethyltrisiloxane and poly(hydro,methyl)(dimethyl)siloxane. The best catalyst appeared to be cyclooctadiene ligand-containing rhodium siloxide complex immobilized on Aerosil which was recycled as many as 20 times without loss of activity and selectivity in hydrosilylation of vinylheptamethyltrisiloxane with heptamethyltrisiloxane. On the ground of CP/MAS NMR measurements it was established that the mechanism of hydrosilylation catalyzed by silica-supported rhodium siloxide complexes is different from that for the complexes in the homogeneous system.     

Die Acidität kristalliner Kieselsäuren

Acidity of Crystalline Silicic Acids Crystalline silicic acids are strong solid acids with surface acidities ranging from H₀ < ?3 (H₂Si₁₄O₂₉ · 5.4 H₂O) to H_O ≈? 2.3(H₂Si₂O₅), measured with Hammett indicators. Thermal dehydration reduces the surface acidity to 2.3–3.3 only. The high acidity probably results from regular, extended hydrogen bonding systems including the surface water molecules. By disturbing the regular array of hydrogen bonds the acidity decreases to H_o = 5–6 which is considered to be the characteristic acidity of isolated silanol groups not involved in regular hydrogen bonding systems. The surface acidity is not directly related to the ease with which the protons are exchanged by alkali ions because of the cooperative nature of the cation exchange.     

Characterization of Surface Modified Silica Nanoparticles by 29Si Solid State NMR Spectroscopy

 Various aerosils surface modified with silane reagents were prepared and investigated by ²⁹Si solid state NMR spectroscopy. The mode of bonding onto the silanol surface (mono- or divalent) can be specified by comparison with chemical shifts from solution. A detailed analysis also leads to the detection of products formed via hydrosilylation reactions. A rough quantification of the surface loading can be obtained by a signal deconvolution process of the silanol resonances on the Aerosil surface.     

Oberflächenverbindungen von Übergangsmetallen. XVIII. Der Einfluß der Cr-Konzentration auf Oxydationszahl und „Qualität”︁ von Cr-Oberflächenverbindungen auf Silicagel

Surface Compounds of Transition Metals. XVIII. The Influence of Cr Concentration on Oxidation Number and “Quality” of Cr Surface Compounds on Silicagel Mean oxidation number (OZ ) and mean unsaturated character (q ) of reduced Cr surface compounds on silicagel depend on the concentration of Cr in the product. The first effect is caused by the decrease of thermally stable surface Cr^VI with increasing Cr concentration in the activated product, since surface Cr^VI is the only precursor of surface Cr^II (constant yield of reduction～90%); consequently OZ _red shifts to higher values with increasing concentration. — The measured decrease of q with increasing Cr content cannot be correlated with a possible coordination of neighbouring SiOH groups, as it was suggested for the influence of T_act and T_red; other explanations are proposed. For the analyzed product, the results support the postulated model of an ensemble of topologically different individual surface species of typical reactivity.     

Versuche zur Hydrolyse der Siloxan-Bindungen an Siliciumdioxid-Oberflächen

Zusammenfassung Am Beispiel des Aerosils wurde die Ver?nderung der Oberfl?che des Siliciumdioxids bei der Entwicklung verschiedener hydrolytischer Agentien untersucht. Die Oberfl?che des Aerosils enthielt ursprünglich neben Silanolgruppen in erheblichem Umfang Siloxangruppen. Mit kaltem Wasser, mit ammoniakalischer Brenzkatechin-L?sung und bei kürzerer Einwirkung von siedendem Wasser wurde eine teilweise Hydrolyse der Siloxan-Bindungen erreicht, doch, wurden nie mehr als 3.3 Silanolgruppen pro 100 ?² erhalten. Nach l?ngerer Einwirkung von siedendem Wasser wurde eine Abnahme der spez. Oberfl?che und der Zahl der Silanolgruppen pro Fl?cheneinheit beobachtet. Im Elektronenmikroskop zeigten die Teilchen dieser Aerosile Hüllen geringerer Dichte aus feinporigem Siliciumdioxid. Infolge der extrem engen Poren wurde ein erheblicher Teil der Oberfl?che und der Silanolgruppen bei den Messungen nicht erfa?t. Konz. Ammoniak und in geringerem Ma?e auch lange Lagerung an der Atmosph?re hatten ?hnliche Wirkung. überhitzter Wasserdampf katalysierte bei 200° die Abspaltung von Wasser aus Silanolgruppen. Die Pr?parate verloren dabei mehr Wasser als bei gleicher Temperatur im Hochvakuum. Die Ergebnisse und die Mechanismen der Ver?nderungen werden diskutiert.

---

Summary The influence of various agents on the surface of Aerosil, a fine particle size silicia was studied. Originally, siloxane as well as silanol groups were present in the Aerosil surface. Partial hydrolysis of the siloxane bonds was achieved with cold water, ammoniacal pyrocatechol solution and after shorter contact with boiling water. The number of silanol groups per 100 ?² never exceeded 3.3. On prolonged action of boiling water a significant decrease of the surface area and of the number of silanol groups was observed. Electron microphotographs show that the particles became coated by a layer of less dense porous silicia. As a result of the extremely narrow pores part of the surface and of the silanol groups escaped detection. Ammonia and, to a lesser extent, prolonged storing at atmospheric conditions had similar effects. At 200 °C the condensation of silanol groups to siloxane bonds was catalyzed by superheated steam as evidenced by a greater loss of silanol groups than in a high vacuum at the same temperature. The results and the mechanisms of the changes in the silica surface are discussed.

---

---

Herrn Prof.U. Hofmann zum 60. Geburtstag gewidmet.

---

Herrn Prof. Dr.U. Hofmann sind wir für stete F?rderung und gro?zügige Unterstützung unserer Arbeiten zu gro?em Dank verpflichtet. Dem Fonds der Chemie und dem Landesgewerbeamt des Landes Baden-Württemberg danken wir für finanzielle Unterstützung.     

Surface Energy of Silica-TEOS-PDMS Ormosils

Inverse gas chromatography (IGC) was applied to characterize the surface energy of organically modified silicates (ormosils) by measuring the interaction of molecular organic probes with the ormosil surface. Ormosils were prepared by the sol-gel method by the reaction of TEOS (tetraethoxysilane), PDMS (polydimethylsiloxane) and different types of silica (Aerosil 130, Aerosil 200 and Aerosil 380). The isosteric heat of adsorption, q _st, and the dispersive component of the surface energy, _s ^D, were estimated by using the retention volume of different nonpolar and polar probes at infinite dilution. The dispersive component shows an increase as the specific surface area of the silica is increased from 29.6 mJ/m² to 51.4 mJ/m² at 60°C. Such values are lower than that obtained for aerosil particles meaning that PDMS chains impede the interaction with silanol groups located on the silica surface. The specific interaction parameter, I^SP, and the enthalpy of specific adsorption, H _a ^SP, of polar probes on the ormosil surface were also measured in order to obtain the acid-base character of ormosil surface. The H _a ^SP, was correlated with the donor, DN, and the acceptor, AN, numbers of the probes to quantify the acidic, K _A, and the basic, K _B, parameters of the substrate surface. The obtained results suggest that the silica particles were covered by PDMS chains in a different way depending on the type of silica used. The values of K _A and K _B suggest that the ormosil surface is amphoteric, with predominantly acceptor electron sites.     

Beiträge zur Chemie der Alkylverbindungen von Übergangsmetallen. XIII. Über die Reaktion von Vanadinsäure-triisopropylester mit Zinkdimethyl—Zur Kenntnis des Methylvanadinoxiddiisopropoxids

Contributions to the Chemistry of Transition Metal Alkyl Compounds. XIII. the Reaction of Vanadium Isopropyl Ester with Dimethyl Zinc. — On the Formation of CH₃VO(i-OC₃H₇)₂ Dimethyl zinc reacts with ortho vanadium acid triisopropyl ester forming methyl zinc isopropoxide (CH₃Zn-i-OC₃H₇)_n and methyl vanadium oxide diisopropoxide CH₃VO(i-OC₃H₇)₂. The new σ-organovanadium compound was isolated and thoroughly characterized.     

Untersuchungen an oxidischen Katalysatoren. XV. Der Einfluß von Oberflächenhydratation und -acidität der Übergangsformen des Aluminiumoxids auf die katalytische Aktivität bei der Dehydratisierung von Isopropanol

Studies on Oxide Catalysts. XV. The Influence of Surface Hydration and Acidity of Transient Forms of Alumina on the Catalytic Activity in the Dehydration of Isopropanol Surface OH groups were determined quantitatively on a aeries fo different samples of transient aluminas by means of D₂O exchange as well as by interaction with thionyl chloride and potassium vapour, and the acid centers were determined by titration with potassium methoxide and high temperature chemisorption of ammonia. Only the deuterium exchange and chemisorption of ammonia proved to be suitable for a quantitative characterization of the surface chemical properties mentioned in the paper. The catalytic activity is dependent directly on the number of acid centers. Between the number of surface OH groups and the results of the catalytic dehydration of isopropanol, however, no correlation was found.     

Beiträge zur Chemie der Alkylverbindungen von Übergangsmetallen. XXI [1] Versuche zur Alkylierung von Vanadin(IV)-chlorid und Vanadinoxidtrichlorid

Inhaltsübersicht. Es wird über Reaktionen von Vanadin(IV)-chlorid mit Zinkdialkylen und Bortrialkylen berichtet. Dabei entstehen aus Vanadin(IV)-chlorid und Zinkdialkylen Komplexe des Vanadin(III)-chlorids, Vanadin(II)-chlorids und von Alkylvanadindichloriden mit Zinkchlorid, Alkylzinkchloriden oder Zinkdialkylen. Bortrialkyle bewirken die Bildung von reaktivem Vanadin(III)-chlorid, das in Komplexe mit Diäthyläther der Formel VCl₃ · n O(C₂H₅)₂ (n = 1–3) übergeführt werden konnte. Contributions to the Chemistry of Transition Metal Alkyl Compounds. XXI. Experiments for the Alkylation of Vanadium Tetrachloride and Vanadium Oxidetrichloride Abstract. It is reported on experiments for alkylating vanadium tetrachloride by means of zinc dialkyls and boron trialkyls. Zinc dialkyls causes the formation of complexes of vanadium tetrachloride, vanadium trichloride and alkyl vanadium dichlorides with zinc chloride, alkyl zinc chlorides and zinc dialkyls. In the reactions with boron trialkyls high reactive vanadium trichloride is formed, which reacts with diethyl ether to complexes with the formula VCl₃ · n O(C₂H₅)₂ (n = 1–3).     

Untersuchungen zur Physisorption und Chemisorption von Wasser auf Zinkoxid-Oberflächen

The investigation of different zinc oxide samples by means of thermogravimetry and infrared spectroscopy has shown that the surface of the samples is covered by an approximately monoatomic layer of hydroxide groups. Furthermore, varying amounts of carbonate groups are found which are due to the presence of zinc hydroxide carbonate II [Zn₅(OH)₆(CO₃)₂]. Below relative water vapour pressures of p/p₀ = 0.2 (25°C), two hydrogen bridges connect one physisorbed water molecule with two chemisorbed surface hydroxide groups. In addition, about the same amount of water is physically adsorbed between vapour pressures of p/p₀ 0.2 and 0.8. At still higher relative humidity, a multimolecular layer is built up which reaches a thickness of about 200 water molecules at p/p₀ = 1.0. All samples show in the v-OH region of the IR. spectrum a broad absorption with four bands, A, B, C, and D. The position of the bands and the change of their intensities when rising the temperature of the samples up to 600°C indicate that both bands of longer wave lengths, C and D, arise from physically adsorbed water molecules, while the bands A and B are due to hydroxide groups located on the crystallographic faces (0001) and (0001 ), respectively.     

Über den Abbau von Kieselsol,Kieselgel und Aerosil in wäßrigen Tetramethylammoniumhydroxidlösungen

On the Degradation of Silicic Acid Sols, Silicic Acid Gel, and Aerosil in Aqueous Tetramethylammonium Hydroxide Solutions Investigations by trimethylsilylation and molybdate methods show that the degradation rate of silicic acid sols in tetramethylammonium (TMA) hydroxide solution depends on their average particle size. Under equivalent conditions (TMA/Si = 1, C = ～1,4 M, T: 25°C) the degradation of a silicic acid sol, silicic acid gel, and Aerosil takes place with different rates, which correlate with the specific surface of the investigated SiO₂ products. Regardless of the SiO₂ source the silicate anions of the three solutions are built up from the same types. During degradation the solutions with the same chemical composition show a similar anion distribution, which differs from analogous TMA-silicate solutions, the anions of which are in an equilibrium state.     

Untersuchungen an katalytisch aktiven Oberflächenverbindungen. VII. Katalytische Eigenschaften von Vanadiumoxid-Chromoxid-Aufschicht-Katalysatoren

Studies on Catalytically Active Surface Compounds. VII. Catalytic Properties of Oxidic Vanadium-Chromium Catalysts The catalytic properties of silica supported vanadium-chromium catalysts for the oxidation of ethanol, butane, propene, and butene are described and completed by ESR measurements. Differences in catalytic activity of chromium-free vanadium catalysts which are caused by different values of the silanol group concentration of the support are shown to become levelled by the addition of chromium. V? O? Cr species of medium catalytic activity are considered to be the catalytic active center. ESR spectra taken after the reaction show the existence of Cr³⁺ and VO⁺² species. A correlation between the intensity of the VO²⁺ signal and the catalytic activity of the samples is observed.     

Hydroxyl‐Mediated Non‐oxidative Propane Dehydrogenation over VOx/γ‐Al2O3 Catalysts with Improved Stability

Supported vanadium oxides are one of the most promising alternative catalysts for propane dehydrogenation (PDH) and efforts have been made to improve its catalytic performance. However, unlike Pt‐based catalysts, the nature of the active site and surface structure of the supported vanadium catalysts under reductive reaction conditions still remain elusive. This paper describes the surface structure and the important role of surface‐bound hydroxyl groups on VO_x / γ‐Al₂O₃ catalysts under reaction conditions employing in situ DRIFTS experiments and DFT calculations. It is shown that hydroxyl groups on the VO_x /Al₂O₃ catalyst (V?OH) are produced under H₂ pre‐reduction, and the catalytic performance for PDH is closely connected to the concentration of V?OH species on the catalyst. The hydroxyl groups are found to improve the catalyst that leads to better stability by suppressing the coke deposition.     

Monomer Protonation‐Dependent Surface Polymerization to Achieve One‐Step Grafting Cross‐Linked Poly(4‐Vinylpyridine) Onto Core–Shell Fe3O4@SiO2 Nanoparticles

Functional polymer‐grafting silica nanoparticles hold great promise in diverse applications such as molecule recognition, drug delivery, and heterogeneous catalysis due to high density and uniform distribution of functional groups and their tunable spatial distance. However, conventional grafting methods from monomers mainly consist of one or more extra surface modification steps and a subsequent surface polymerization step. A monomer protonation‐dependent surface polymerization strategy is proposed to achieve one‐step uniform surface grafting of cross‐linked poly(4‐vinylpyridine) (P4VP) onto core–shell Fe₃O₄@SiO₂ nanostructures. At an approximate pH, partially protonated 4VP sites in aqueous solution can be strongly adsorbed onto deprotonated silanol groups ( Si O⁻) onto Fe₃O₄@SiO₂ nanospheres to ensure prior polymerization of these protonated 4VP sites exclusively onto Fe₃O₄@SiO₂ nanoparticles and subsequent polymerization of other 4VP and divinylbenzene monomers harvested by these protonated 4VP monomers onto Fe₃O₄@SiO₂ nanoparticles, thereby achieving direct grafting of cross‐linked P4VP macromolecules onto Fe₃O₄@SiO₂ nanoparticles.     

3d Metal complexes with 2-hydroxy-3-methoxybenzaliminopropyl and 4-hydroxy-3-methoxybenzaliminopropyl immobilized on aerosil as catalysts of ozone decomposition

The composition and structure of M(II) (Mn, Co, Cu) complexes with Schiff bases (L1 = 2-hydroxy-3-methoxybenzaliminopropyl, L2 = 4-hydroxy-3-methoxybenzaliminopropyl) immobilized on Aerosil and their catalytic activity in ozone decomposition were studied. The formation of pseudotetrahedral bisligand complexes M(L1)₂ and pseudooctahedral complexes M(L2)₂ on the modified surface of Aerosil was confirmed by IR and ESR spectroscopy and by diffuse reflectance spectroscopy (DSR). The catalytic activity of isostructural complexes in ozone decomposition varies in the order Mn > Co > Cu, and M(L₂)₂ complexes are more active than M(L1)₂.