This Review documents some examples of recent innovations in the field of catalytic selective oxidation from an industrial point of view. The use of alkanes as building blocks for the synthesis of bulk chemicals and intermediates is discussed, along with the main properties that catalysts should possess in order to efficiently catalyse the selective oxidation of these hydrocarbons. The currently developed processes for propene oxide and new processes under investigation for the synthesis of adipic acid are also described, highlighting innovative aspects for a better sustainability of the chemical industry.
Stable to 150 °C, the heterocyclic carbene 1 is characterized by the typical reactivity of a nucleophilic carbene. Dihydrotriazole 1 can be prepared by simple thermal decomposition of its methanol adduct. X‐ray crystal structure analysis, ab initio calculations, and reactivity studies confirm the nucleophilic carbene character of 1.
Titanium Silicalite-1 (TS-1) shows an outstanding ability to catalytically epoxidize olefins with hydrogen peroxide (H2O2), leaving only water as byproduct. 1,2 Despite the industrial use of the TS-1/H2O2 system for the production of more than one million tons of propylene oxide per year, 3 the active site structure remains elusive, although it has been studied for almost 40 years by spectroscopic and computational methods. 4-10 TS-1 is a zeotype of MFI structure in which a small fraction of Si-atoms (1-2 %) are substituted by Ti, and its catalytic properties are generally attributed to isolated Ti(IV) sites. 1 Herein, we analyze a series of highly active and selective TS-1 propylene epoxidation catalysts. By UV-Vis and Raman spectroscopy, as well as electron microscopy, we show that Ti is well-dispersed in all samples, with formation of small TiOx clusters at high Ti-loadings. Most notably, irrespective of Ti-content, all samples show a characteristic solid-state 17 O NMR signature when contacted with H2 17 O2, indicating the formation of bridging peroxo species on dinuclear Tisites. Using DFT (density functional theory) calculations, we propose a mechanism of propylene epoxidation on a dinuclear site, in which the cooperativity between two titanium atoms enables a low-energy reaction pathway where the key oxygen-transfer transition state bears strong resemblance to that of olefin epoxidation by peracids.The active species in TS-1 are commonly proposed to be isolated Ti(IV) sites bearing peroxo 11 or hydroperoxo moieties, 12 although the involvement of terminal Ti-oxo and activated H2O2 on Ti(IV) has also been discussed (Fig. 1a,b). 7 In contrast, the only homogeneous Ti-based epoxidation catalysts able to efficiently utilize H2O2 as primary oxidant are dinuclear, such as the Berkessel-Katsuki epoxidation catalyst 1 (Fig. 1c). [14][15][16][17][18][19] While the structural characterization of molecular systems is well-established and has enabled the isolation of peroxo compounds, obtaining information on the structure of Ti-sites in TS-1 with molecular-level precision has proven more challenging.Recent work by some of us has shown that solid-state 17 O NMR spectroscopy is a powerful tool for understanding and assessing the reactivity of peroxo species. 20 Oxygen-17 is an NMRactive quadrupolar nucleus whose spectroscopic properties can be readily measured by solidstate NMR and computed by DFT. The NMR signature (chemical shift and quadrupolar coupling) is highly sensitive to the symmetry and electronic structure around the oxygen atoms. We thus reasoned that 17 O NMR spectroscopy would be a valuable tool to harness the signature of the active sites in TS-1 and thereby probe their structure. In this study, we investigate five TS-1 samples prepared in the BASF laboratories (Table 1). 21,22 Two of these samples have a Ti-content of 1.9 wt%, one of which was prepared on hundred-kg scale (sample 1), the other three samples have Ti-loadings of 1.5 wt%, 1.0 wt%, and 0.5 wt%. The five samples have surface areas between 4...
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