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Iridium-catalyzed carbonylations with iodide promoters

Iridium complexes catalyze carbonylation of CH3OH to acetic acid, also with an iodide promoter. The reaction rate relative to Rh is much slower. The steps in the reaction sequence are similar to those for Rh, but the kinetics are more complex . Complex interactions involve HjO, the form of the iodide promoter and CO pressure . For example, at high concentration of 1 ion, the rate increases with increasing pressure. At low 1 levels and low HjO concentration, the reaction rate is inversely dependent on CO pressure. Catalyst species under these different reaction conditions include IrfCOljI, IrH(CO)2l2(OH2), [Ir(CH3)(CO)2l3] and [IrH(CO)2l3] . In acetophenone solvent at 175°C and 3 MPa, the reaction is first-order in CH3OH and independent of CH3I at concentrations in which the I Ir ratio is >20 . Under some conditions, the water gas shift reaction becomes important careful control is necessary for high efficiencies to acetic acid. [Pg.539]

In the mid-1960s, Paulik and Roth at Monsanto Co discovered that rhodium and an iodide promoter were more efficient than cobalt, with selectivities of 99% and 85%, with regard to methanol and CO, respectively. Moreover, the reaction is operated under significantly milder conditions such as 40-50 bar pressure and around 190 °C [8]. Even though rhodium was 1000 times more costly than cobalt at this time, Monsanto decided to develop the rhodium-based catalyst system mainly for the selectivity concerns, and thus for the reduction of the process cost induced by the acetic acid purification, even if it was necessary to maintain a 14% w/w level of water in the reactor to keep the stability of the rhodium catalyst. In addition, Paulik et al. [9] demonstrated that iridium can also catalyze the carbonylation of methanol although at a lower rate. However, it is noteworthy that the catalytic system is more stable, especially in the low partial pressure zones of the industrial unit. [Pg.260]

The mechanism of the cobalt- (BASF), rhodium- (Monsanto), and iridium- (Cativa) catalyzed reaction is similar but the rate-determining steps differ and different intermediate catalyst complexes are involved. In all three processes two catalytic cycles occur. One cycle involves the metal carbonyl catalyst (II) and the other the iodide promoter (i). For a better overview only the catalytic cycle of the rhodium-catalyzed Monsanto process is presented in detail (Figure 6.15.4). Initially the rhodium iodide complex is activated with carbon monoxide by forming the catalytic active [Rhi2(CO)2] complex 4. Further the four-coordinated 16-electron complex 4 reacts in the rate-determining step with methyl iodide by oxidative addition to form the six-coordinated 18-electron transition methyl rhodium (I II)... [Pg.745]


See other pages where Iridium-catalyzed carbonylations with iodide promoters is mentioned: [Pg.204]    [Pg.206]    [Pg.278]    [Pg.278]    [Pg.6423]    [Pg.147]    [Pg.324]    [Pg.746]    [Pg.4]    [Pg.26]    [Pg.34]    [Pg.433]   
See also in sourсe #XX -- [ Pg.97 ]




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Carbonyl iodides

Carbonylation catalyzed

Carbonylation promotions

Carbonylation, iridium-catalyzed

Catalyzed Carbonylations

Iodide promoters

Iodides carbonylation

Iridium carbonylation

Iridium carbonyls

Iridium-catalyzed carbonylations

Promoters carbonylation

Promotion with

With iridium

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