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Support inorganic

Immobilized ionic liquids Chloroaluminate ionic liquids on inorganic supports IGI, UK 2001 27... [Pg.31]

The described bioaffinity separations demonstrate that polyacrylamide spacers aid the selective binding of highly complex and delicate biomacromolecules and their associates. Moreover, these solutes remain biologically active after desorption probably due to the high inertness and flexibility of the surrounding polymer chains fixed on the solid support. The unbound parts of serum usually show no loss of the activities of their constituents. Thus we evaluate the surface of inorganic supports coated with chemisorbed iV-hydroxyethyl polyacrylamide and its derivatives as being biocompatible. [Pg.172]

Alumina supported sodium metaperiodate, which can be prepared by soaking the inorganic support with a hot solution of sodium metaperiodate, was also found to be a very convenient reagent for the selective and clean oxidation of sulphides to sulphoxides79. The oxidation reaction may be simply carried out by vigorous stirring of this solid oxidant with the sulphide solution at room temperature. As may be expected for such a procedure, solvent plays an important role in this oxidation and ethanol (95%) was found to be... [Pg.246]

Probably the first non-covalent immobilization of a chiral complex with diazaligands was the adsorption of a rhodium-diphenylethylenediamine complex on different supports [71]. These solids were used for the hydride-transfer reduction of prochiral ketones (Scheme 2) in a continuous flow reactor. The inorganic support plays a crucial role. The chiral complex was easily... [Pg.183]

These processes are very rapid and allow the preparation of inorganic supports in one step. This technique allows large-scale manufacturing of supports such as titania, fumed silica, and aluminas. Sometimes the properties of the material differ from the conventional preparation routes and make this approach unique. Multicomponent systems can be also prepared, either by multimetallic solutions or by using a two-nozzle system fed with monometallic solutions [22]. The as-prepared powder can be directly deposited onto substrates, and the process is termed combustion chemical vapor deposition [23]. [Pg.122]

Surface area is one of the most important factors in determining throughput (amount of reactant converted per unit time per unit mass of catalyst). Many modem inorganic supports have surface areas of 100 to >1000 m g The vast majority of this area is due to the presence of internal pores these pores may be of very narrow size distribution to allow specific molecular sized species to enter or leave, or of a much broader size distribution. Materials with an average pore size of less than 1.5-2 nm are termed microporous whilst those with pore sizes above this are called mesoporous materials. Materials with very large pore sizes (>50 nm) are said to be macroporous, (see Box 4.1 for methods of determining surface area and pore size). [Pg.88]

Industrial catalysts are usually composed of inorganic supports and metals on the supports. They are often prepared by heat treatment of metal ions on the support at high temperature sometimes under hydrogen. They have very complex structures. For example, they are the mixtures of metal particles with various sizes and shapes. Metal particles often strongly interact with the inorganic supports, thus resulting in the structure of half balls. [Pg.65]

Supported metal catalysts, M°/S, are typically two-components materials built up with a nanostructured metal component, in which the metal centre is in the zero oxidation state (M°), and with an inorganic support (S), quite various in its chemical and structural features [1], M° is the component typically deputed to the electronic activation of the reagents involved in the catalyzed reactions. S is typically a microstructured component mainly deputed to the physical support and to the dispersion of M° nanoclusters. [Pg.201]

The resulting M°/CFP nanocomposites with M = Pd, Pt, Ag and Au exhibit in general satisfactory handiness in the laboratory atmosphere and chemical stability under operational conditions, re-usability, mechanical robustness (under proper conditions), plain filterability. Their reactivity is quite comparable to that of conventional M°/ S (S = carbon, inorganic support) catalysts. M°/CFP are to be employed in the liquid phase. [Pg.229]

Cyanide complexes have a venerable history (see CCC S )),1 and find utilization in many industrial processes including as synthetic catalysts e.g., Co cyanides on inorganic supports catalyze alkylene oxide polymerization,187 molecular magnetic materials, in electroplating, and in mining. Their pharmacology and toxicology is well explored... [Pg.19]

Since 1985, several thousands of publications have appeared on complexes that are active as catalysts in the addition of carbon monoxide in reactions such as carbonylation of alcohols, hydroformylation, isocyanate formation, polyketone formation, etc. It will therefore be impossible within the scope of this chapter to review all these reports. In many instances we will refer to recent review articles and discuss only the results of the last few years. Second, we will focus on those reports that have made use explicitly of coordination complexes, rather than in situ prepared catalysts. Work not containing identified complexes but related to publications discussing well-defined complexes is often mentioned by their reference only. Metal salts used as precursors on inorganic supports are often less well defined and most reports on these will not be mentioned. [Pg.142]

Direct Reaction between the Solid Support and the Metal Complex 9.9.2.2.1 Inorganic supports... [Pg.446]

Three approaches have been tested, as already described above for inorganic supports. The first attempts concern the direct reaction of transition metal carbonyls with unmodified organic polymers like poly-2-vinyl-pyridine.61 62 However, this kind of anchoring is restricted to only a few complexes. Various polymers have been functionalized with donor groups 63-72 ligand displacement reactions using these afforded the corresponding immobilized complexes. Finally, tests with modified complexes and unmodified polymers are scarce because of the low stability of these complexes under the conditions of reactions. [Pg.451]

Weetall, H.H. (1993) Preparation of immobilized proteins covalently coupled through silane coupling agents to inorganic supports. Applied Biochemistry and Biotechnology, 41, 157-188. [Pg.107]

In order to overcome some limitations of the adsorption process due to surface accessibility or diffusional hindering, immobilization of enzymes by direct in situ encapsulation has been investigated. When inorganic supports can be prepared in mild conditions compatible with the enzyme stability, then such processes allow... [Pg.449]

Modeling of enzyme adsorption isotherms on an inorganic support using the Scatchard equation Equation (1) allow one to determine the binding constant. [Pg.472]


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See also in sourсe #XX -- [ Pg.75 ]

See also in sourсe #XX -- [ Pg.98 ]

See also in sourсe #XX -- [ Pg.99 ]




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Carbon formation using inorganic support

Carbon using inorganic supports

Catalysts systems inorganic-supported

Chromium trioxide inert inorganic support

Covalent using inorganic supports

Heterogeneous Enantioselective Catalysis Using Inorganic Supports

Immobilization systems inorganic support

Inorganic Oxides as Supports for Organometallic Species

Inorganic membranes supported

Inorganic membranes supports

Inorganic oxide support

Inorganic solid supports

Inorganic support compounds, catalyst

Inorganic supports advantages

Inorganic supports bond formation

Inorganic supports catalysts

Inorganic supports covalent anchoring

Inorganic supports functionalization

Inorganic supports polymerization

Inorganic supports, covalent immobilization

Inorganic-organic hybrid supports

Microwave inorganic supported reagent

Oxidation using inorganic supports

Polymer supported metal catalysts inorganic-organic hybrid

Porous Inorganic Materials as Potential Supports for Ionic Liquids

Resin properties inorganic support

Supported inorganic oxide

Supported liquid membranes inorganic support

Supported metals inorganic electrolyte effect

Supported reagents inorganic based

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