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Spectroscopy infrared of adsorbed species

A. A. Davydov, Infrared spectroscopy of adsorbed species on the surfaces of transition metal oxides, Wiley, Chichester, 1990. [Pg.212]

A.V. Kiselev and V.I. Lygin, in Infrared Spectroscopy of Adsorbed Species, L.H. Little (Ed.), Academic Press, New York, 1966. [Pg.243]

A.A. Davydov and C.H. Rochester, Infrared Spectroscopy of Adsorbed Species on the Surface of Transition Metal Oxides, Wiley, New York, 1990. [Pg.243]

Little, L. H. "Infrared Spectroscopy of Adsorbed Species" Academic Press New York 1966. [Pg.305]

More recently, the work of Lipkowski and coworkers has sought to quantify the application of the SSR in the study of adsorbed species. Lipkowski and coworkers have built up a quantitative treatment of the infrared spectroscopy of adsorbed species based upon the SSR in an elegant series of papers [16, 83, 85, 165, 170, 171] using the combination of SNIFTIRS and conventional electrochemical techniques such as differential capacitance measurements. Thus, Li, Roscoe, and Lipkowski [165] published a study in 1999 on the adsorption of the benzoate anion at... [Pg.558]

Infrared Spectroscopy. The infrared spectroscopy of adsorbates has been studied for many years, especially for chemisorbed species (see Section XVIII-2C). In the case of physisorption, where the molecule remains intact, one is interested in how the molecular symmetry is altered on adsorption. Perhaps the conceptually simplest case is that of H2 on NaCl(lOO). Being homo-polar, Ha by itself has no allowed vibrational absorption (except for some weak collision-induced transitions) but when adsorbed, the reduced symmetry allows a vibrational spectrum to be observed. Fig. XVII-16 shows the infrared spectrum at 30 K for various degrees of monolayer coverage [96] (the adsorption is Langmuirian with half-coverage at about 10 atm). The bands labeled sf are for transitions of H2 on a smooth face and are from the 7 = 0 and J = 1 rotational states Q /fR) is assigned as a combination band. The bands labeled... [Pg.634]

The first chapter of this volume, by Sheppard and de la Cruz, addresses the application of vibrational spectroscopy for the characterization of adsorbed hydrocarbons. This chapter is a successor to the 1958 Advances in Catalysis chapter about infrared spectra of adsorbed species, authored by the pioneers Eischens and Pliskin. Vibrational spectroscopy continues to provide some of the most incisive techniques available for determination of adsorbate structures. The present chapter is concerned with introductory principles and spectra of adsorbed alkenes a sequel is scheduled to appear in a subsequent volume of Advances in Catalysis. [Pg.446]

The identification of species adsorbed on surfaces has preoccupied chemists and physicists for many years. Of all the techniques used to determine the structure of molecules, interpretation of the vibrational spectrum probably occupies first place. This is also true for adsorbed molecules, and identification of the vibrational modes of chemisorbed and physisorbed species has contributed greatly to our understanding of both the underlying surface and the adsorbed molecules. The most common method for determining the vibrational modes of a molecule is by direct observation of adsorptions in the infrared region of the spectrum. Surface spectroscopy is no exception and by far the largest number of publications in the literature refer to the infrared spectroscopy of adsorbed molecules. Up to this time, the main approach has been the use of conventional transmission IR and work in this area up to 1967 has been summarized in three books. The first chapter in this volume, by Hair, presents a necessarily brief overview of this work with emphasis upon some of the developments that have occurred since 1967. [Pg.300]

In this paper we report a study of the activity of CU/AI2O3 solids with various copper contents towards the reduction of NO by propane in the presence of oxygen. The nature of the superficial copper species is determined by infrared spectroscopy of adsorbed CO and NO. The results are compared to the catalytic activity. [Pg.592]

The infrared spectroscopy of adsorbed CO and NO has allowed us to determine the nature of the copper species at the surface of the alumina support. [Pg.603]

Basils, M.R. "Applied Spectroscopy Reviews", 1968, 1, 289 Little, L.H. "Infrared Spectra of Adsorbed Species" ... [Pg.229]

Knowledge of the stracture and bonding of molecnles to snrfaces has been obtained from such techniques as LEED, electron energy-loss spectroscopy (EELS), secondaiy-ion mass spectrometry (SIMS), infrared spectroscopy (IRS), Raman spectroscopy, and NMR spectrometiy. The scope of snch studies needs to be greatly expanded to include the effects of coadsorbates, promoters, and poisons. Greater emphasis should be given to developing new photon spectroscopies that would permit observation of adsorbed species in the presence of a gas... [Pg.172]

The most common application of infrared spectroscopy in catalysis is to identify adsorbed species and to study the way in which these species are chemisorbed on the surface of the catalyst. Sometimes infrared spectra of adsorbed probe molecules such as CO and NO give valuable information on adsorption sites on a catalyst. We will first summarize the theory behind infrared absorption. [Pg.155]

Photocatalytic oxidation is a novel approach for the selective synthesis of aldehyde and acid from alcohol because the synthesis reaction can take place at mild conditions. These reactions are characterized by the transfer of light-induced charge carriers (i.e., photogenerated electron and hole pairs) to the electron donors and acceptors adsorbed on the semiconductor catalyst surface (1-4). Infrared (IR) spectroscopy is a useful technique for determining the dynamic behavior of adsorbed species and photogenerated electrons (5-7). [Pg.463]

The objective of this study is to investigate the mechanism of propylene oxidation by a transient infrared spectroscopic technique over Rh/Al203. This technique allows simultaneous measurement of the dynamics of adsorbed species by in situ infrared spectroscopy and the product formation profile by mass spectrometry. [Pg.404]

It has long been realised that infrared (IR) spectroscopy would be an ideal tool if applied in situ since it can provide information on molecular composition and symmetry, bond lengths and force constants. In addition, it can be used to determine the orientation of adsorbed species by means of the surface selection rule described below. However, IR spectroscopy does not possess the spatial resolution of STM or STS, though it does supply the simplest means of obtaining the spatially averaged molecular information. [Pg.95]

Summarizing, infrared spectroscopy measures, in principle, force constants of chemical bonds. It is a powerful tool in the identification of adsorbed species and their bonding mode. Infrared spectroscopy is an in situ technique, which is applicable in transmission or diffuse reflection mode on real catalysts, and in reflection-absorption mode on single crystal surfaces. Sum frequency generation is a speciality... [Pg.242]

See other pages where Spectroscopy infrared of adsorbed species is mentioned: [Pg.248]    [Pg.248]    [Pg.404]    [Pg.489]    [Pg.639]    [Pg.104]    [Pg.150]    [Pg.442]    [Pg.456]    [Pg.389]    [Pg.392]    [Pg.572]    [Pg.405]    [Pg.331]   
See also in sourсe #XX -- [ Pg.634 ]



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