MoS2 formation induced by amorphous MoS3 species under lubricated friction.

Amide molybdate has been recently introduced as a friction modifier for tribological applications. Combined with zinc dithiophosphate (ZDDP) and fatty amines, it provides an ultralow friction coefficient. The ultimate product of Mo compound transformations in tribological contact, due to frictional heating and shearing, as well as chemical interactions with oil additives, is molybdenum sulfide (MoS2). Understanding the decomposition of amide molybdate leading to MoS2 is of primary importance to the optimization of the design of lubricant formulations. This study focuses on the investigation by Raman spectroscopy of amide molybdate decomposition intermediates. Raman spectra of tribofilms, obtained after friction tests under different temperatures and pressures, revealed the formation of an amorphous MoS3 intermediate coexisting with MoS2. However, under severe conditions, the tribofilms are mostly composed of MoS2.

Enhanced hydrogen release by catalyzed hydrolysis of sodium borohydride-ammonia borane mixtures: a solution-state 11B NMR study.

Hydrolysis of mixtures consisting of sodium borohydride NaBH(4) (SB) and ammonia borane NH(3)BH(3) (AB) was studied in the absence/presence of a Co catalyst. The kinetics of the H(2) evolutions was measured. The reactions were followed in situ by solution-state (11)B NMR and the hydrolysis by-products characterized by NMR, XRD and IR. It is demonstrated that the combination of the two compounds gives a synergetic effect. SB rapidly reduces the Co catalyst precursor and the NH(4)(+) ions from AB contribute in the dispersion of the in situ formed Co nanoparticles. As a result, the kinetics of H(2) evolution is greatly improved. For instance, a hydrogen generation rate of 29.6 L min(-1) g(-1)(Co) was found for a mixture consisting of 81 wt% NH(3)BH(3), 9 wt% NaBH(4) and 10 wt% CoCl(2). By (11)B NMR, it was showed that the reaction mechanisms are quite trivial. As soon as the Co catalyst forms in situ, SB, rather than AB, hydrolyzes until it is totally converted. Then, the overall hydrolysis continues with that of AB. Both reactions follow a bimolecular Langmuir-Hinshelwood mechanism; no reaction intermediates were observed during the process. In fact, SB and AB convert directly into B(OH)(4)(-), which comes in equilibrium with a polyborate compound identified as B(3)O(3)(OH)(4)(-). All of these results are discussed herein.

Compensation effect and volcano curve in toluene hydrogenation catalyzed by transition metal sulfides.

Within the framework of volcano curves, a kinetic study of toluene hydrogenation catalyzed by transition metal sulfides highlights the variation of the apparent kinetic parameters as a function of the ab initio sulfur-metal bond energy descriptor and sulfo-reductive reaction conditions.

Multi-component fitting XAFS analysis of molybdate species during catalyst preparation ration by the molten salt method.

The goal of the present study was to elucidate the formation mechanisms of highly dispersed catalysts by the molten salt method. For this purpose, multi-component fitting Mo K-edge EXAFS analysis was applied to the structure of molybdate catalysts prepared in KNO3 and NaNO3. The analysis revealed that MoO3 dissolved in molten salts was at first transformed into polymolybdate anions and finally into MoO(4)2- anions. The transformation into MoO(4)2- anions took place at a lower temperature when NaNO3 was used as molten salt than KNO3. In contrast, polymolybdate anions were stable even at higher temperature when ZrO2 was added as a support of molybdate.