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And pyramidal structure

Two carborane cations, zV/ -2,3,4,5,6-McsC5BBr+ and the tentatively proposed arachno-N ci WX I71, were reported. The identity and pyramidal structure of the pentacarbaborane cation was determined by X-ray crystallography.112 The small arachno-carborane was detected on the basis of ab initio computations and 11B NMR data in the mixture from reaction of the 2-propyl cation with diborane.113 Two neutral adducts based on the pentacarbaborane cation, ///V/9-2,3,4,5,6-McsCsBBKCI2 (R = Cl or SiClj), were made from MesCsSiMe3 or (MesCs Si with B2CI4, respectively.114 The BCI3 adduct was structurally characterized by X-ray crystallography. [Pg.55]

Molecular geometry liin imum Except for dihedral angles and pyramidal structures where use of polarization functions is needed... [Pg.52]

Scheme 4.5 Experimental evidence for planar and pyramidal structures. Scheme 4.5 Experimental evidence for planar and pyramidal structures.
The sulphite ion, SO3, has a pyramidal structure and the short S—O bond length suggests the presence of double bonding, i.e. [Pg.291]

Figure 4.11 Electron micrographs of polyethylene crystals, (a) Dark-field illumination shows crystals to have a hollow pyramid structure. (Reprinted with permission from P. H. Geil, Polymer Single Crystals, Interscience, New York, 1963.) (b) Transmission micrograph in which contrast is enhanced by shadow casting [Reprinted with permission from D. H. Reneker and P. H. Geil, /. Appl. Phys. 31 1916 (I960).]... Figure 4.11 Electron micrographs of polyethylene crystals, (a) Dark-field illumination shows crystals to have a hollow pyramid structure. (Reprinted with permission from P. H. Geil, Polymer Single Crystals, Interscience, New York, 1963.) (b) Transmission micrograph in which contrast is enhanced by shadow casting [Reprinted with permission from D. H. Reneker and P. H. Geil, /. Appl. Phys. 31 1916 (I960).]...
EPR studies and other physieal methods have provided the basis for some insight into the detailed geometiy of radieal species.Deduetions about strueture ean also be drawn from the study of the stereoehemistiy of reactions involving radical intermediates. Several structural possibilities must be considered. If discussion is limited to alkyl radicals, the possibilities include a rigid pyramidal structure, rapidly inverting pyramidal structures, or a planar structure. [Pg.675]

The broad conclusion of all these studies is that alkyl radicals are shallow pyramids and that the barrier to inversion of the pyramidal structures is low. Radicals also are able to tolerate some geometric distortion associated with strained ring systems. [Pg.679]

The most important members of this class are the osmium nitrido, and the osmyl complexes. The reddish-purple K2[OsNCl5] mentioned above is the result of reducing the osmiamate. The anion has a distorted octahedral structure with a formal triple bond Os=N (161pm) and a pronounced /ram-influence (pp. 1163-4), i.e. the Os-Cl distance trans to Os-N is much longer than the Os-Cl distances cis to Os-N (261 and 236 pm respectively). The anion [OsNCls] also shows a rram-effect in that the Cl opposite the N is more labile than the others, leading, for instance, to the formation of [Os NCl4] , which has a square-pyramidal structure with the N occupying the apical position. [Pg.1085]

Compare electrostatic potential maps for planar and pyramidal forms of 2-methyl-2-propyl anion. For which is the negative charge more delocalized Is this the lower-energy structure For this case, does charge delocalization lead to stabilization Explain. [Pg.42]

These compounds are generally believed to have square pyramidal structures (X-ray, PPr3) [157d] and have typical spectroscopic properties of transition-metal hydrides (IrHCl2(PBu2Me)2 i/(Ir—H) 1998 cm-1). [Pg.150]

M(NO)Cl2(PPh3)2. Both these compounds have a square pyramidal structure with bent apical M-N-0 linkage and similar bond angles. There is, however, a difference of 70cm-1 in t/(N-0). [Pg.167]

M(NO)(OCOCF3)2(PPh3)2. Both these complexes have 5-coordinate geometries with monodentate carboxylates. The rhodium compound has a square pyramidal structure with bent Rh-N-O (122°) but the iridium compound has a tbp structure with straight equatorial Ir-N—O (178°). The position of i/(N—O) reflects this difference (1800 cm-1 (Ir) and 1665 cm-1 (Rh)). [Pg.167]

Many of the nitrosyls studied are 5-coordinate, and analysis of crystallographic results indicates that, in general, in the trigonal bipyramid structures NO is found in the equatorial position in a linear geometry whereas in a square pyramidal structure, there is a bent M—N—O linkage in an apical position. A further point of interest is that in compounds like Ir(NO)Cl2(PPh3)2, the nitrosyl group bends in the more hindered (P—Ir—P) plane. [Pg.167]

A number of tertiary phosphine complexes with bulky ligands (Figure 3.80) have modified square pyramidal structures, examples being M(I)3Br2, Pt(II)3Br2 and Pd(III)3Br2 (all X-ray) [136]. [Pg.236]

Radicals with very polar substituents e.g. trifluoromethyl radical 2), and radicals that arc part of strained ring systems (e.g. cydopropyl radical 3) arc ct-radicals. They have a pyramidal structure and are depicted with the free spin resident in an spJ hybrid orbital. nr-Radicals with appropriate substitution are potentially chiral, however, barriers to inversion are typically low with respect to the activation energy for reaction. [Pg.12]

The reactivities of the various phosphinyl radicals with monomers have been examined (Table 3. lO).283-465,467-475 Absolute rate constants are high, lying in the range 106-I08 M 1 s 1 and show some solvent dependence. The rate constants are higher in aqueous acetonitrile solvent than in methanol. The high magnitude of the rate constants has been linked to the pyramidal structure of the phosphinyl radicals.46- ... [Pg.132]

Thus the x-ray data do not decide between this structure and a truly plane structure. Evidence from another source is at hand, however. A plane C03= or N03 ion should show three characteristic fundamental vibrational frequencies. These have been observed as reflection maxima in the infra-red region. But two of the maxima, at 7 m and 14m, are double,27 and this doubling, which is not explicable with a plane configuration, is just that required by a pyramidal structure, the separation of the components giving the frequency of inversion of the pyramid.28... [Pg.81]

Transannular interaction via the electron-delocalization mechanism was found, but lessened by 10-15% for the ligand superhyperfine splitting and 30-35% for the hyperfine splitting (62) in the epr spectrum. The crystal structure of [VOS2CNEt2)2] shows that the molecular core has the expected C2V symmetry [V-0 = 159.1(4), V-S = 138.7(2)-241.0(2) pm] (63). Magnetic and spectral data provided evidence for a tetragonal, pyramidal structure (VII) for these complexes. Like many other coordinatively unsaturated, metal... [Pg.219]

Compounds of the type [PeX(R2dtc)2] have been obtained by treating [Fe(R2dtc)3] complexes with concentrated hydrohalic acids. [FeCl(Et2dtc)3] has been studied by Hoskins and White (264) it has a square pyramidal structure, with the chlorine atom at the apex, and with the Fe atom situated 62 pm above the basal plane of the four sulfur atoms. A similar structure is found (265) for the monoiodo derivative [FeI(Et2dtc)2]. The chloro complex has been synthesized (266) by the following reaction. [Pg.244]

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See also in sourсe #XX -- [ Pg.232 ]



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