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Desorption surface analysis

Lykke K R and Kay B D 1990 State-to-state inelastic and reactive molecular beam scattering from surfaces Laser Photoionization and Desorption Surface Analysis Techniquesvo 1208, ed N S Nogar (Bellingham, WA SPIE) p 1218... [Pg.919]

An introduction to the principles behind SPI-SALI, this ankle presents a theoretical discussion of why SPI-SALI is much less fragmenting than MPI-SALI. Examples are shown which describe the additional fragmentation induced by the desorption beam—in this case ESD is compared to ion sputtering. The main focus of the article is the advantages of SPI-SALI for surface analysis of bulk organic polymers. [Pg.570]

Laser desorption methods (such as LD-ITMS) are indicated as cost-saving real-time techniques for the near future. In a single laser shot, the LDI technique coupled with Fourier-transform mass spectrometry (FTMS) can provide detailed chemical information on the polymeric molecular structure, and is a tool for direct determination of additives and contaminants in polymers. This offers new analytical capabilities to solve problems in research, development, engineering, production, technical support, competitor product analysis, and defect analysis. Laser desorption techniques are limited to surface analysis and do not allow quantitation, but exhibit superior analyte selectivity. [Pg.737]

Desorption Electrospray Ionization (DESI). DESI is a novel gentle ionization method for surface analysis (Figure 2.6).[19,20] Like classical ESI, it operates at atmospheric pressure. No sample preparation is required. A solvent passes through the capillary of the electrospray source charged droplets are produced (primary ions) and they are directed to a solid sample. Their impact with the surface causes sample molecules to be ionized and... [Pg.52]

There is a wealth of information available on CO chemisorption over single-crystal and polycrystalline platinum surfaces under ultrahigh-vacuum conditions research efforts in this area have gained a significant momentum with the advent of various surface analysis techniques (e.g., 2-8). In contrast, CO chemisorption on supported platinum catalysts (e.g., 9, 10, 11) is less well understood, due primarily to the inapplicability of most surface-sensitive techniques and to the difficulties involved in characterizing supported metal surfaces. In particular, the effects of transport resistances on the rates of adsorption and desorption over supported catalysts have rarely been studied. [Pg.79]

In conclusion, TDS of adsorbates on single crystal surfaces measured in ultrahigh vacuum systems with sufficiently high pumping speeds provides information on adsorbate coverage, the adsorption energy, the existence of lateral interactions between the adsorbates, and the preexponential factor of desorption, which in turn depends on the desorption mechanism. Analysis of spectra should be done with care, as simplified analysis procedures may easily give erroneous results. [Pg.48]

Secondary ion (mass spectrometry) SIMS Particle induced desorption/ ionization Nonvolatile molecular ions Semiconductors Surface analysis Imaging... [Pg.18]

Mass spectrometric measurements of ions desorbed/ionized from a surface by a laser beam was first performed in 1963 by Honig and Woolston [151], who utilized a pulsed mby laser with 50 p,s pulse length. Hillenkamp et al. used microscope optics to focus the laser beam diameter to 0.5 p,m [152], allowing for surface analysis with high spatial resolution. In 1978 Posthumus et al. [153] demonstrated that laser desorption /ionization (LDI, also commonly referred to as laser ionization or laser ablation) could produce spectra of nonvolatile compounds with mass > 1 kDa. For a detailed review of the early development of LDI, see Reference 154. There is no principal difference between an LDI source and a MALDI source, which is described in detail in Section 2.1.22 In LDI no particular sample preparation is required (contrary to... [Pg.34]

With a focus on trace forensic detection of explosives, especially for use in counterterrorism and to counter narcotics investigations, Fetterolf et al. [75] evaluated the use of ion mobility-mass spectrometry for explosives determinations. In this, explosives residues were collected on a membrane filter by a special attachment on a household vacuum cleaner. Although subsequent thermal desorption and analysis required only 5 s, fimits of detection for most common explosives were as low as 200 pg. The persistence of explosives on hands and transfer to other surfaces were also examined as were post-blast residues of NG on fragments of improvised explosive devices constructed with double-based smokeless powder. Finally, postblast residue from C-4, Semtex, and other explosives was found by IMS analyses on items of forensic and evidentiary value. These few out of many examples demonstrate that mobihty spectrometers are well suited tools for laboratory and on-site investigations, before and after the use of explosives. [Pg.198]

If the slightly soluble, surface-active compound is spread as a mono-layer, the film is unstable and desorbs from the surface. Analysis of the kinetics of desorption follows the treatment given by Ter Minassian-Saraga (29). Immediately upon spreading the monolayer, film molecules... [Pg.123]

Laser Desorption/FTMS. Laser desorption (LD)/FTMS [20] has been applied to a variety of chemical problems, ranging from fundamental studies of ion-molecule reactions [21,22], to the analysis of pharmaceuticals [4,23-29], to polymers [7,30-35], to organometallics [6-39], and to surface analysis [4,40], The large number of papers being generated from the few laboratories working... [Pg.68]

M. G. Sherman, J. R. Kingsley, J. C. Hemminger, and R. T. Mclver, Jr., "Surface Analysis by Laser Desorption of Neutral Molecules with Detection by Fourier-Transform Mass Spectrometry," Anal. Chim. Acta., 178 (1), 79-89 (1985). [Pg.80]

Now possibilities of the MC simulation allow to consider complex surface processes that include various stages with adsorption and desorption, surface reaction and diffusion, surface reconstruction, and new phase formation, etc. Such investigations become today as natural analysis of the experimental studying. The following papers [282-285] can be referred to as corresponding examples. Authors consider the application of the lattice models to the analysis of oscillatory and autowave processes in the reaction of carbon monoxide oxidation over platinum and palladium surfaces, the turbulent and stripes wave patterns caused by limited COads diffusion during CO oxidation over Pd(110) surface, catalytic processes over supported nanoparticles as well as crystallization during catalytic processes. [Pg.434]

Laser Desorption. A laser microprobe system has been used for surface analysis to detect both organic and inorganic species [89]. Although this instrument was not developed with elemental analysis in mind, studies of selected inorganic compounds have been carried out, and elemental ions have been and can be detected with the system. One other external source that produces atomic ions should be noted here. A laser vaporization metal ion source [90] has produced a wide variety of reactant ions for use in ion-molecule reactivity studies. In almost all cases, pure metals were used to form the ions, and the intent of the research was chemical reactivity studies and not elemental analysis. [Pg.358]

Spectroscopic Characterization of Heterogeneous Catalysts. Part A. Methods of Surface Analysis. Part B. Chemisorption of Probe Molecules, J.L.G. Fierro. Ed.. Elsevier (1990). (Part A on surface structure methods, surface groups on oxides. X-ray, Mdssbauer Part B on Infrared, NMR, EPR, thermal desorption,. ..)... [Pg.146]

The aim of this work is to test and to compare the performances of various nitrogen adsorption-desorption isotherms analysis methods. These models were applied to model samples obtained by mechanically mixing two micro- and mesoporous solids respectively in perfectly known proportions. The relevant morphological characteristics of the porous texture of the mixtures, such as the specific surface and volume, are physically additive. A criterion that allows determining the reliability of the analysis methods tested is thus to check the linearity of the relation between a given parameter and the weight percentage of the pure solids. [Pg.419]

In the FIM the ions are generated at the surface from incident neutrals. In other ion-probe methods the incident beam is already ionized and three major features may be distinguished when it interacts with a surface sputtering and desorption, ion neutralization, and ion scattering. Detection of secondary ions forms the basis of secondary-ion mass spectrometry (SIMS) which is well established as a technique for surface analysis (see ref 208 for a previous review in this series) while ion-neutralization spectroscopy (INS) yields both structural and bonding information on surface species (see ref 209). [Pg.71]

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See also in sourсe #XX -- [ Pg.934 ]



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