Chemical bonds transition metal compounds

This chemical bond between the metal and the hydroxyl group of ahyl alcohol has an important effect on stereoselectivity. Asymmetric epoxidation is weU-known. The most stereoselective catalyst is Ti(OR) which is one of the early transition metal compounds and has no 0x0 group (28). Epoxidation of isopropylvinylcarbinol [4798-45-2] (1-isopropylaHyl alcohol) using a combined chiral catalyst of Ti(OR)4 and L-(+)-diethyl tartrate and (CH2)3COOH as the oxidant, stops at 50% conversion, and the erythro threo ratio of the product is 97 3. The reason for the reaction stopping at 50% conversion is that only one enantiomer can react and the unreacted enantiomer is recovered in optically pure form (28). 

Metal-metal (M-M) bonds, first noted in the early sixties, occur in several thousand transition-metal compounds [1]. Complex technetium compounds and compounds with M-M bonds (clusters) have been studied more extensively than many other classes of inorganic compounds. Increasing interest in technetium compounds is due to the practical uses of the "mTc isotope, which ranks first among radioactive isotopes used in nuclear medicine diagnostics [2-4]. On the other hand, technetium clusters are an interesting object for theoretical studies, because until recently, they were the only compounds in which the presence of these anomalous chemical bonds was thought possible. 

Sigma-bonded transition metal complexes are able to polymerize a range of vinyl monomers, the only limitation being that the monomer should not have groups that react chemically with the transition metal compound. An important observation is that styrene and its derivatives are polymerized by the sigma complexes. In this respect they differ from the jr-allyl compounds that show no reactivity at all toward these monomers. A reasonable explanation for this is that the mechanism of the initiation is different... 

In this chapter, we ll look at the properties and chemical behavior of transition metal compounds, paying special attention to coordination compounds, in which a central metal ion (or atom)—usually a transition metal—is attached to a group of surrounding molecules or ions by coordinate covalent bonds (Section 7.5). 

Oxides of transition metal compounds need special consideration for CFSE since d-electrons are involved in chemical bonding. Then Eq. 25 may be written ... 

Studies on dinuclear transition-metal compounds containing metal-metal bonds have deeply enriched our understanding of chemical bonding. The nature and... 

The results for Cr34 and the 3d5 cations Fe3+ and Mn2+ show that it is possible to derive values of the Racah B parameter for transition metal compounds from absorption bands in their crystal field spectra, enabling comparisons to be made with field-free ion values. In all cases, there is a decrease of the Racah B parameter for the bonded cations relative to the gaseous ions, which is indicative of diminished repulsion between 3d electrons in chemical compounds of the transition metals. This reduction is attributable to electron delocalization or covalent bonding in the compounds. Such decreases of Racah B parameters are expressed as the nephelauxetic Greek , cloud expanding) ratio, p, given by... 

Supports used for obtaining Ziegler-Natta catalysts can differ essentially from one another. Some of the supports may contain reactive surface groups (such as hydroxyl groups present in specially prepared metal oxides) while others do not contain such reactive functional groups (such as pure anhydrous metal chlorides). Therefore, the term supported catalyst is used in a very wide sense. Supported catalysts comprise not only systems in which the transition metal compound is linked to the support by means of a chemical covalent bond but also systems in which the transition metal atom may occupy a position in a lattice structure, or where complexation, absorption or even occlusion may take place [28]. The transition metal may also be anchored to the support via a Lewis base in such a case the metal complexes the base, which is coordinatively fixed on the support surface [53,54]. 

Supported precursors for Ziegler-Natta catalysts may be obtained, depending on the kind of support, in two ways by treatment of the support containing surface hydroxyl groups with a transition metal compound with chemical covalent bond formation, and by the treatment of a magnesium alkoxide or magnesium chloride support with a Lewis base and transition metal compound with coordination bond formation. 

The low values of dissociation energy of a bond metal-carbon are characteristic particularly for alkyl transition-metal compounds. Some of them are the key intermediates of Ziegler-Natta low-pressure polymerization of alkenes. Outside the laboratory or chemical plant [43, 44], Nature gives us also important representatives of such compounds namely vitamin B12 or coenzyme B12. 

The distribution of electrons over d orbitals in complexes of different geometry controls the most stable geometric configuration. This principle can also be used to understand the chemical bonding of transition metal compounds and their surfaces. We will illustrate this first by analyzing the relative stability of octahedral NiO versus trigonal prismatic M0S2. 

Nuclear quadrupole coupling constants can thus provide much valuable information about chemical bonding in transition metal compounds since they can be obtained both for the metal and, or for the attached atom in many cases. There are, however, a number of disadvantages inherent in the technique. The resonances are often of very low intensity thus necessitating a large sample size (up to 10 grams). Furthermore, the complete region of interest, 2—1,000 MHz, cannot be covered by one... 

Articles dealing with the structure and chemistry of solid and crystal surfaces include Tabor (1981) and Forty (1983), who discusses metals and catalysts in particular. The surface of diamond is discussed by Pate (1986), metal oxides by Henrich (1985), transition-metal compounds by Langell and Bernasek (1979), and transition-metal oxides by Henrich (1983). Some of these articles deal with the electronic structures of the surfaces as well as the surface atom geometry the volume edited by Rhodin and Ertl (1979) on the nature of the surface chemical bond and the review paper by Tsukada et al. (1983) on the electronic structure of oxide surfaces concentrate on this aspect. One of the few reviews directed specifically towards minerals is that of Berry (1985). 

Metal carbides with the NaCl structure have been paid much attention to its remarkable physical properties, such as extreme hardness, very high melting points, and metallic-like electric conductivity [1,2]. Being significantly less reactive than most metals, the compounds have been used as cold cathode emitters. It is essential to understand the bond nature of these compounds for practical use of their physical properties. However, few attempts to study the chemical bonding of these compounds have been made until now. The aim of the present work is to examine TiC and UC as typical examples of transition and heavy metal carbides and to compare their bond natures in connection with their physical properties. 

The term hydro has been used throughout in this article in preference to the more commonly used terms hydride or hydrido. These latter terms imply that the hydrogen atom bonded to a transition metal has a high electron density comparable to the saline hydrides of Groups lA and IIA. A number of hydro-transition metal compounds do, indeed, show chemical behavior characteristic of a hydridic hydrogen. However, this is in no way general, and, since it is a particularly poor assumption for the compounds of platinum, the use of the term hydro should avoid any misconception on the part of the reader not familiar with this area of chemistry. 

The properties of transition metal compounds and coordination complexes are determined, in large part, by the participation of d electrons in bonding and chemical reactions. 

Most transition metals have a number of stable oxidation states that lead to different kinds of chemical bonds and facilitate electron transfer reactions. Molecular orbital theory satisfactorily describes bonding in transition metal compounds and coordination complexes. 

Frenking, G., Pidun, U. Ab initio studies of transition-metal compounds the nature of the chemical bond to a transition metal. J. Chem. 

This very short intermezzo on the electronic structure of transition metal compounds had as its main purpose to illustrate that bonding is very similar to that in molecular co-ordination compounds. Hence their chemical reactivity can be understood using the same concepts. 

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