Surface species formate

Kolyagin YG, Ivanova II, Ordomsky VV, Gedeon A, Pirogov YA. Methane activation over Zn-modified MFI zeolite NMR evidence for Zn-methyl surface species formation. J Phys Chem C 2008 112 20065-9. 

After reviewing various earlier explanations for an adsorption maximum, Trogus, Schechter, and Wade [244] proposed perhaps the most satisfactory one so far (see also Ref. 243). Qualitatively, an adsorption maximum can occur if the surfactant consists of at least two species (which can be closely related) what is necessary is that species 2 (say) preferentially forms micelles (has a lower CMC) relative to species 1 and also adsorbs more strongly. The adsorbed state may also consist of aggregates or hemi-micelles, and even for a pure component the situation can be complex (see Section XI-6 for recent AFM evidence of surface micelle formation and [246] for polymeric surface micelles). Similar adsorption maxima found in adsorption of nonionic surfactants can be attributed to polydispersity in the surfactant chain lengths [247], Surface-active impuri-... 

This reaction is catalyzed by iron, and extensive research, including surface science experiments, has led to an understanding of many of the details (72). The adsorption of H2 on iron is fast, and the adsorption of N2 is slow and characterized by a substantial activation energy. N2 and H2 are both dis so datively adsorbed. Adsorption of N2 leads to reconstmction of the iron surface and formation of stmctures called iron nitrides that have depths of several atomic layers with compositions of approximately Fe N. There is a bulk compound Fe N, but it is thermodynamically unstable when the surface stmcture is stable. Adsorbed species such as the intermediates NH and NH2 have been identified spectroscopically. 

Carbon dioxide has been proposed as an additive to improve the performance of lithium batteries [60]. Aurbach et al. [61] studied the film formed on lithium in electrolytes saturated with C02, and using in situ FTIR found that Li2C03 is a major surface species. This means that the formation of a stable Li2C03 film on the lithium surface may improve cyclability [62], Osaka and co-workers [63] also studied the dependence of the lithium efficiency on the plating substrate in LiC104-PC. The addition of C02 resulted in an increase in the efficiency when the substrate was Ni or Ti, but no effect was observed with Ag or Cu substrates. 

Lithium carbonate and hydrocarbon were identified in XPS spectra of graphite electrodes after the first cycle in LiPF6/EC-DMC electrolyte [104]. Electrochemical QCMB experiments in LiAsF6/EC-DEC solution [99] clearly indicated the formation of a surface film at about 1.5 V vs. (Li/Li+). However the values of mass accumulation per mole of electrons transferred (m.p.e), calculated for the surface species, were smaller than those of the expected surface compounds (mainly (CF OCC Li ). This was attributed to the low stability of the SEI and its partial dissolution. 

At high alkali coverages (near monolayer coverage), when the adsorbed alkali overlayer shows a metal-like character, alkali-methoxy species are formed. As shown by TPD experiments in the system K/Ru(001) these alkali-methoxy species are more stable than the methoxy species on clean Ru(001) and adsorbed methanol on 0.1K/Ru(001). On metal surfaces inactive for methanol decomposition, e.g. Cu(lll), these alkali-methoxy species are formed even at low alkali coverages, due to the weaker interaction of the alkali atoms with the metal surface. The formation of these species stabilizes the methoxy species on the metal surface and enhances the activity of the metal surface for methanol decomposition. 

We did not extensively discuss the consequences of lateral interactions of surface species adsorbed in adsorption overlayers. They lead to changes in the effective activation energies mainly because of consequences to the interaction energies in coadsorbed pretransition states. At lower temperatures, it can also lead to surface overlayer pattern formation due to phase separation. Such effects cannot be captured by mean-field statistical methods such as the microkinetics approaches but require treatment by dynamic Monte Carlo techniques as discussed in [25]. 

Gas-phase methylation of catechol by methanol was studied on y -AI2O3 modified by the basic elements K, Li, Mg and Ca. Addition of 7.5 at.% Mg to y-AljOa was optimal and increased the 3-methyl catechol selectivity from 0.26 to 0.65. X-ray diffraction experiments showed the diffusion of Li and Mg cations into the y -AI2O3 bulk. This induces a change in the surface species (XPS data) and the surface acid-base properties (TPD experiments). Ca and K addition to y-alumina was ineffective due to formation of basic oxide layers on the sur ce. 

The goal of this work was to determine surface species present under reaction conditions, and to investigate the interactions of adsorbed NO and NO2 with CH4. Infrared spectra were collected under reaction conditions, and in various mixtures of NO, O2, NO2, and CH4. It was of particular interest to make direct observations of the factors affecting the formation of NO2 and its reaction with CH4, since NO2 has been suggested as an intermediate in the reduction of NO by CH4. A further objective was to elucidate the pathway by which N2 and CO2 are formed. 

Figure 9.6 Visual representation of the platinum oxide growth mechanism, (a) Interaction of H2O molecules with the Pt electrode occurring in the 0.27 V < < 0.85 V range, (b) Discharge of 5 ML of H2O molecules and formation of 5 ML of chemisorbed oxygen (Ochem)- (c) Discharge of the second ML of H2O molecules the process is accompanied by the development of repulsive interactions between (Pt-Pt) -Ofi m surface species that stimulate an interfacial place exchange of Ochem and Pt surface atoms, (d) Quasi-3D surface PtO lattice, comprising Pt and moieties, that forms through the place-exchange process. (Reproduced with permission...

The backbone of the DeNOx process over mononuclear TMI encaged in zeolites can be epitomized in the form of three interconnected cycles associated with the formation of the N2 and 02 reaction products (Figure 2.6), inferred from the steady state and transient rate data combined with spectroscopic evidence for surface species and... 

Complementary in-situ characterization of the surface species using infrared (IR) spectroscopy has provided information on the identity and coverage of the surface species involved in the NO catalytic reduction [56]. It was found that the changes observed in the surface coverages of NO and CO correlate well with the observed changes in N20 selectivity mentioned above below 635 K, where N20 formation is favored, NO is the major adsorbate on the surface, whereas above 635 K, where N2 formation is preferred,... 

Haneda et al. [134,135] studied the formation and reaction of adsorbed species in NO reduction by propene over Ga203-Al203. IR transient reaction technique was employed to examine the reactivity and dynamic behaviour of surface species. The catalyst was first exposed to either C3H6/02/Ar or NO/Oz/Ar at 623 K for a long time to form and accumulate the surface species. The catalyst was further purged with pure Ar and the reaction gas then switched to various gas mixtures. Changes in the intensity of IR bands were measured with time on stream. The main surface species detected by IR during... 

The study of the transformation of 5-alkoxyalkyl-5-alkyl-l,3-dioxanes provided the first experimental evidence that the conformation of the reactant molecule plays a determining role regarding the direction of the catalytic reaction. The reason for the differing reaction directions clearly indicates that the conformers adsorb in different ways.32 The 5-alkoxyethyl isomers can exist in their chair conformations (1 and 2 in Scheme 4.12). The main reaction of the adsorbed surface species is the formation of an ester (3) by the rupture of the C-O bond in the ring. In one of the two isomers (1) the R2-0 group can also be adsorbed and this adsorption leads to a smaller ester molecule (4). 

Meunier, F.C., Tibiletti, D., Goguet, A., Shekhtman, S., Hardacre, C., and Burch, R. 2007. On the complexity of the water-gas shift reaction mechanism over a Pt/Ce02 catalyst Effect of the temperature on the reactivity of formate surface species studied by operando DRIFT during isotopic transient at chemical steady-state. Catal. Today 126 143 17. 

A dissociative adsorption of methanol forming surface methoxy groups is suggested as the initial step. This is followed by the slow step, the formation of some form of adsorbed formaldehyde species. Evidence.for the bridged species is not available, experiments with °0 labeled methanol are expected to clarify this. Continued surface oxidation leads to a surface formate group and to carbon monoxide. All the byproducts can be obtained by combination of the appropriate surface species. 

Cp CpZrMe2]/Al203 (5oo) (216 h-1) [185]. Typically, highly dehydroxylated alumina (Al203.(iooo)) is a better support, and it has been associated with the formation of cationic surface species. 

The direction of the potential shift of the surface C-N band is the same as for the C-O band on Pt and the shift rates are ca. 30 cm 1/V for Ag and Au (22,23,25) and ca. 45 cm-1/V for Cu (33). The measurement for copper is less accurate due to formation of ion complexes with large absorption crossections and the relatively weak signal from the surface species itself. 

The reduction of carbon monoxide also suffers deactivation by a surface species similar to that for carbon dioxide reduction but which forms at lower temperatures. The reduction of carbon monoxide does appear to proceed via a path similar to that which the reduction of carbon dioxide follows. Rates for methanol reduction are extremely variable. Methanol reduction, like carbon dioxide reduction, both increases in rate with decreasing pH until the surface becomes blocked with surface hydrogen and is also deactivated by increased temperature. For methanol, deactivation does not occur by the formation of the same surface species. 

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