Mass high-pressure

The thenuodynamic quantities are derived from equilibrium measurements as a fiinction of temperature. The measurements are frequently made in a high-pressure mass spectrometer [107]. The pertinent equation is In... 

Kebarle P 1988 Pulsed eleotron high pressure mass speotrometer Techniques for the Study of Ion-Molecule Reactions ed J M Farrar and W FI Saunders Jr (New York Wiley)... 

Szule]ko J E and McMahon T B 1991 A pulsed electron beam, variable temperature, high pressure mass... 

This volume eontains exeellent diseussions of the various methods for studying ion-moleeule reaotions in the gas phase, ineluding high pressure mass speotrometry, ion eyelotron resonanee speotrosoopy (and FT-ICR) and seleeted ion flow tube mass speotrometry. 

Method (b) corresponds to the usual method of investigating ion-molecule reactions in a high pressure mass spectrometer although charge exchange with slow ions is used instead of electron impact. After preliminary work (9, 23), the method was fully developed by Szabo 20, 21, 22). 

The Use of High Pressure Mass Spectrometry to Determine the Energy Dependence of Ion-Molecule Reaction Rates... 

High Pressure Mass Spectrometry with a m.e.v. Proton Beam... 

The advent of techniques that enable the study of fast reactions in the gas phase, such as ion cyclotron resonance (ICR) spectrometry, Fourier-transform ion cyclotron resonance spectrometry (FT-ICR) and high pressure mass spectrometry (HPMS), allowed the measurement of the gas-phase proton affinities for strong bases84-86 as well as for... 

The important and stimulating contributions of Kebarle and co-workers 119 14 > provide most of the data on gas-phase solvation. Several kinds of high pressure mass spectrometers have been constructed, using a-particles 121>, proton- 123>, and electron beams 144> or thermionic sources 128> as primary high-pressure ion sources. Once the solute A has been produced in the reaction chamber in the presence of solvent vapor (in the torr region), it starts to react with the solvent molecules to yield clusters of different sizes. The equilibrium concentrations of the clusters are reached within a short time, depending on the kinetic data for the... 

Tandem mass spectrometry H6,i46) both stationary 116> and flowing afterglow-methods 118,147) and drift tube techniques U6> have also been applied to some of the clustering reactions. Results for the gas-phase solvation of H+ by H2O and NH3 generally agree well with the values obtained by high pressure mass spectro-metric observations 148). 

Table 10. Thermodynamic data for individual clustering steps in derived by high pressure mass spectrometry gas-phase solvation of H+, ...

Williamson, D.H. Knighton, W.B. Grimsrud, E.P. Effect of Buffer Gas Alterations on the Thermal Electron Attachment and Detachment Reactions of Azu-lene by Pulsed High Pressure Mass Spectrometry. Int. J. Mass Spectrom. 2000, 795/796,481-489. 

In the present review, a new variation on an existing experimental method will be used to show how accurate unimolecular dissociation rate constants can be derived for thermal systems. For example, thermal bimolecular reactions are amenable to study by use of several, now well-known, techniques such as (Fourier transform) ion cyclotron resonance spectrometry (FTICR), flowing afterglow (FA), and high-pressure mass spectrometry (HPMS). In systems where a bimolecular reaction leads to products other than a simple association adduct, the bimolecular reaction can always be thought of as containing a unimolecular... 

The instruments used for the experimental work detailed in this review are several high-pressure mass spectrometers (HPMS) and a Fourier transform ion cyclotron resonance spectrometer (FTICR). Each of the instruments was constructed, to a considerable degree, in-house at the University of Waterloo, and each contains features unique to its type of apparatus. The instruments in general and the unique features of the Waterloo apparatus in particular are described below. 

Figure 1. Schematic of the reverse geometry double-focusing high-pressure mass spectrometer.

In order to better understand the detailed dynamics of this system, an investigation of the unimolecular dissociation of the proton-bound methoxide dimer was undertaken. The data are readily obtained from high-pressure mass spectrometric determinations of the temperature dependence of the association equilibrium constant, coupled with measurements of the temperature dependence of the bimolecular rate constant for formation of the association adduct. These latter measurements have been shown previously to be an excellent method for elucidating the details of potential energy surfaces that have intermediate barriers near the energy of separated reactants. The interpretation of the bimolecular rate data in terms of reaction scheme (3) is most revealing. Application of the steady-state approximation to the chemically activated intermediate, [(CH30)2lT"], shows that. 

These data thus show that high-pressure mass spectrometry can, in addition to its many other impressive capabilities, be a powerful tool for the determination of lifetimes of transient intermediates on the 10 s timescale. 

Pressure dependence analysis. Kofel and McMahon pointed out that if the apparent bimolecular association rate constant is measured as a function of pressure, k and can be obtained from the slope and intercept of the pressure plot, provided that k and k are independently known k is often taken equal to the Langevin or ADO orbiting rate constant k (the strong collision assmnption), and kf is either taken equal to k or is measured independently by high-pressure mass spectrometry. 

To overcome this, instrumental techniques such as pulsed high-pressure mass spectrometry (PHPMS), the flowing afterglow (FA) and allied techniques like the selected-ion flow tube (SIFT), and ion cyclotron resonance (ICR) spectrometry and its modem variant, Fourier transform mass spectrometry (FTMS), have been developed. These extend either the reaction time (ICR) or the concentration of species (PHPMS, FA), so that bimolecular chemistry occurs. The difference in the effect of increasing the pressure versus increasing the time, in order to achieve bimolecular reactivity, results in some variation in the chemistry observed with the techniques, and these will be addressed in this review as needed. 

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