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Carbon monoxide bond length

Further examples of coordinate bonds are found in metal carbonyl complexes. Metal carbon (carbon monoxide) bond distances in a selection of (first-row) transition-metal carbonyls and transition-metal organometallics are examined in Table 5-11. As expected, Hartree-Fock models do not perform well. The 6-3IG model is clearly superior to the STO-3G and 3-2IG models (both of which lead to completely unreasonable geometries for several compounds), but still exhibits unacceptable errors. For example, the model shows markedly different lengths for the axial and equatorial bonds in iron pentacarbonyl, in contrast to experiment where they are nearly the same. Hartree-Fock models cannot be recommended. [Pg.145]

The PM3 semi-empirical model turns in a surprisingly good account of metal-carbon (carbon monoxide) bond distances in these compounds. While PM3 is not as good as the best of the (density functional) models, individual bond lengths are typically within a few hundredths of an A from their respective experimental values, and larger deviations are uncommon. In view of cost considerations, PM3 certainly has a role in transition-metal structural chemistry. [Pg.148]

As with metal-carbon monoxide bonds, the MP2/6-3IG model does not lead to results of the same calibre as those from density functional models (except local density models). The model actually shows the opposite behavior as 6-3IG, in that bond lengths are consistently shorter than experimental values, sometimes significantly so. In view of its poor performance and the considerable cost of MP2 models (relative to density functional models), there seems little reason to employ them for structural investigations on organometallics. [Pg.149]

Calculate the bond length, ioni7 ation potential, and dipole moment of carbon monoxide by MNDO,. AMI, and PM3,... [Pg.297]

DiisononylPhthalate andDiisodeeylPhthalate. These primary plasticizers are produced by esterification of 0x0 alcohols of carbon chain length nine and ten. The 0x0 alcohols are produced through the carbonylation of alkenes (olefins). The carbonylation process (eq. 3) adds a carbon unit to an alkene chain by reaction with carbon monoxide and hydrogen with heat, pressure, and catalyst. In this way a Cg alkene is carbonylated to yield a alcohol a alkene is carbonylated to produce a C q alcohol. Due to the distribution of the C=C double bond ia the alkene and the varyiag effectiveness of certain catalysts, the position of the added carbon atom can vary and an isomer distribution is generally created ia such a reaction the nature of this distribution depends on the reaction conditions. Consequendy these alcohols are termed iso-alcohols and the subsequent phthalates iso-phthalates, an unfortunate designation ia view of possible confusion with esters of isophthaUc acid. [Pg.122]

In structure II (numbered 13 in the IRC output), the C-H bond has lengthened with respect to the transition structure (1.23 versus 1.09A), while theC-O bond length has contracted slightly. Both changes are what would be expected as formaldehyde dissociates to form carbon monoxide and hydrogen molecule. ... [Pg.178]

Step through the sequence of structures representing dissociation oiketene to methylene and carbon monoxide. Plot energy (vertical axis) vs. carbon-carbon bond distance (horizontal axis). Would you describe ketene as a weak complex between singlet methylene and carbon monoxide Explain. (A table of CC and CO bond lengths is found at left.) Is there an energy barrier to the dissociation ... [Pg.244]

We describe as rigid-body rotation any molecular motion that leaves the centre of mass at rest, leaves the internal coordinates unaltered, but otherwise changes the positions of the atomic nuclei with respect to a reference frame. Whereas in a simple molecule, such as carbon monoxide, it is easy to visualize the two atoms vibrating about a mean position, i.e. with the bond length changing periodically, we may sometimes find it easier to see the vibration in our mind s eye if we think of one atom being stationary while the other atom moves relative to it. [Pg.465]

Carbon Monoxide. There are close similarities between carbon monoxide and nitrogen. The molecules are isoelectronic, and the bond lengths and dissociation energies are quite comparable. The phase diagrams of the two compounds show the same trends in the moderate pressure range with a variety of phase transitions between essentially alike crystal structures [333], when allowance is made for the lack of the inversion center and the presence of a weak electric dipole moment in carbon monoxide. However, the behavior and stability at higher... [Pg.172]

Density functional models provide a much better account. The local density model does the poorest and BP and B3LYP models do the best, but the differences are not great. As with metal-carbon (carbon monoxide) lengths, bond distances from all-electron 6-3IG calculations are usually (but not always) shorter than those obtained... [Pg.148]

Metal-carbon monoxide ligand bond lengths in these same compounds have already been provided in Table 5-11. [Pg.149]

Acetylium tetrafluoroborate was prepared in this way as early as 194324. and the structures of at least two acyl cations have been investigated by X-ray diffraction methods25-27. As expected, CH ,-C=0+ is linear about the central carbon, with a CO bond length of 1.12 A, just shorter than in carbon monoxide, and a very short C-C bond length of 1.38 A25 26. Structurally, therefore, the acyl cations closely resemble the isoelectronic nitriles. [Pg.65]

The production of two moles of carbon monoxide and the 18-electron rule lead us to predict that the acetylene molecule is acting as a four-electron donor. In fact this is just one of many complexes in which alkynes bind in this fashion.81 For example, the structure of the diphenylacetylene complex in Fig. 15.26 shows that the positions of the two rhodium atoms are such as to allow overlap with both tr orbitals in the carbon-carbon triple bond.82 The extent of back donation into the antibondirg orbitals determines the lengthening of the C—C bond and the extent to which the C—H bonds are bent away from the complex. Bond length values vary greatly from system to... [Pg.869]

The very labile dinitrogen complex [Mo(CO)(N2)(Ph2PCH2-CH2PPh2)2] has been described in detail. Its immediate precursor, [Mo(CO)(Ph2PCH2CH2PPh2)2], is obtained by the reaction of [Mo(N2)2-(Ph2PCH2CH2PPh2)2] with, for example, benzyl propionate under carefully controlled conditions (283, 322). This precursor is square pyramidal in the solid state, with carbon monoxide at the apex and an essentially vacant coordination position trans to it. The CO bond length is 1.192(12) A, and v(CO) = 1690 cm 1, and the nearest ap-... [Pg.204]


See other pages where Carbon monoxide bond length is mentioned: [Pg.145]    [Pg.145]    [Pg.225]    [Pg.37]    [Pg.457]    [Pg.108]    [Pg.113]    [Pg.14]    [Pg.13]    [Pg.71]    [Pg.369]    [Pg.329]    [Pg.534]    [Pg.38]    [Pg.64]    [Pg.153]    [Pg.287]    [Pg.59]    [Pg.77]    [Pg.45]    [Pg.209]    [Pg.757]    [Pg.4]    [Pg.8]    [Pg.438]    [Pg.33]    [Pg.2055]    [Pg.67]    [Pg.180]    [Pg.181]    [Pg.61]   
See also in sourсe #XX -- [ Pg.770 ]




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