Electron impact mass spectrometry of alkanes in supersonic molecular beams

Dagan, S.; Amirav, Aviv

doi:10.1016/s1044-0305(94)00095-h

Cited by 61 publications

(70 citation statements)

References 36 publications

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“…This process enhances the relative abundance of the molecular ions considerably. [11] The spectral properties of all products presented in this work are in excellent agreement with their structures, and are consistent with those described in the literature. We are presenting here only relevant data of the new compounds.…”

Section: Generalsupporting

confidence: 89%

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN

Rozen

Golan

2003

Eur J Org Chem

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Tetrasubstituted epoxides, and especially electron‐depleted ones, generally are difficult to prepare. HOF·CH3CN complex, probably the best oxygen transfer agent known today, epoxidizes tetrasubstituted alkenes at 0 °C in a matter of minutes or less in excellent yields. HOF·CH3CN complex is very easy to prepare by bubbling diluted fluorine (commercial) through aqueous acetonitrile. (© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2003)

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Section: Generalsupporting

confidence: 89%

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN

Rozen

Golan

2003

Eur J Org Chem

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“…32 With the conventional EI, normal hydrocarbons show only barely detectable M +. whereas such ions dominate in spectra obtained with SMB.…”

Section: Electron Impact Ionizationmentioning

confidence: 99%

Fourier Transform-Ion Cyclotron Resonance-Mass Spectrometer as a New Tool for Organic Chemists

Pyrek¹

1999

Synlett

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Currently, mass spectral determination of molecular weights and elemental compositions of synthetic products is a common practice. It is aided by truly impressive developments in methods and instrumentation enabling to characterize great variety of compounds including even those of a relatively high molecular weight. Confidence in such measurements, however, depends upon selecting a suitable ionization method, unambiguous identification of a molecular-type ion, and the adequate precision of mass determinations. This review addresses major aspects of the ion formation and analysis with special attention given to the ion-cyclotron resonance. This powerful technique, different in its principle from most other methods of ion analysis, offers a superb combination of ion manipulation and measurement parameters and full compatibility with an array of ionization methods.Key words: mass spectrometry, ultra-high resolution mass spectrometry, ion-cyclotron-resonance, soft ionization, stable isotopes, molecular weight determination. Trapping ions in the ICR-cell 2.3.3.Detection of the trapped ions 2.3.4.Getting ions into the ICR Cell 2.4.Tandem mass spectrometry 2.4.1.Tandem mass spectrometry with magnetic-sectors and quadrupoles 2.4.2.Tandem-MS with FT-ICR-MS 3.Ion formation 3.1. Overview 3.2.Electron impact ionization 3.3.Chemical ionization 3.4.Fast atom bombardment 3.5.Matrix assisted laser desorption/ionization 3.6. Cationization 3.7.Electrospray ionization 4.Mass spectrometry and molecular weight determination 4.1.Stable isotopes and molecular ions 4.2.Isotopic depletion and substitution 4.3.High or ultra-high resolution? 4.4.Mass measurement accuracy 4.5.Can molecular weight be unequivocally determined by mass spectrometry? IntroductionMass spectrometry (MS) is the technique that renders mass-to-charge ratios (m/z) and relative intensities of ions formed (with exceptions), separated, and detected in the high vacuum. The remarkable analytical potentials of MS have been immediately recognized by its inventor J. J. Thomson and, in years immediately following the First World War, the detection and precise characterization of isotopes of almost all elements have been achieved employing the very first mass spectrographs and spectrometers. 1 With some delay, however, these seminal discoveries have been followed by a systematic effort to analyze organic compounds. Ever since, thanks to a steady progress in techniques and instrumentation, MS continues to serve in a variety of inorganic and organic applications. Moreover, by gaining truly astonishing capabilities in terms of ionization, mass range, sensitivity, and accuracy, MS methods cover classes of compounds that originally have been considered as entirely unsuitable for such an analysis.2 Still, as exemplified by the recent synthesis of two diterpenoids, 3 synthetic work can be carried out with the complete omission of MS. As a rule, however, MS data are used to confirm MW and to replace elemental analyses of the final reaction products. Only seldom, synthetic p...

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“…Under these conditions the electron energy is the only parameter that governs the degree of ion fragmentation [14,31,32], and the ion source temperature is irrelevant to the molecule and molecular ion dissociation, while the response time is always ultra-fast. This feature is achieved in a Brink-type open ion source design, which has the electron filament close to the ion cage, that is usually at a relatively high temperature.…”

Section: Ei-ms Of Methomyl Obtained With Fast Gc-ms In 5mb (mentioning

confidence: 99%

Fast, very fast, and ultra-fast gas chromatography-mass spectrometry of thermally labile steroids, carbamates, and drugs in supersonic molecular beams

DAGAN¹,

AMIRAV²

1996

Journal of the American Society for Mass Spectrometry

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Aviv 69978, Tel Aviv, Israel Gas chromatography-mass spectrometry (GC-MS) analyses of thermally labile compounds have been studied by using a short column fast gas chromatograph, coupled with fly-through electron ionization in supersonic molecular beams. Thirty-two compounds, which include steroids, carbamate pesticides, antibiotic drugs, and other pharmaceutical compounds, have been analyzed and the details of their GC-MS analysis are provided. The ability to analyze thermally labile compounds is discussed in relation to the speed of analysis. A new term, "speed enhancement factor" (SEF), is defined as the product of column length reduction and the carrier gas linear velocity increase, as compared with normal GC-MS conditions. Fast, very fast, and ultra-fast GC-MS are defined with a SEF in the ranges of 5-30,30-400, and 400-4000, respectively. Trade-offs in the degree of dissociation, speed, gas chromatograph resolution, and sensitivity were studied and examined with thermally labile molecules . The experimental factors that affect the dissociation are described with emphasis on its reduction. We claim that the use of supersonic molecular beams for sampling and ionization provides the ultimate capability in the GC-MS of thermally labile compounds. The obtained 70-eV electron ionization mass spectra are shown, and an enhanced relative abundance of the molecular ion is demonstrated together with library search capability of these mass spectra, which is better than that reported with particle beam liquid chromatography-mass spectrometry. The performance of fast GC-MS in supersonic molecular beams is compared with other methods of fast GC-MS and with particle beam liquid chromatography-mass spectrometry. (J Am Soc Mass Spectrom 1996, 7, 737-752) G as chromatography-mass spectrometry (GC-MS) is the central technique employed today for the analysis of organic compounds, which includes analysis at trace levels in complex mixtures. However, GC-MS is limited in its scope and therefore is often replaced by liquid chromatography-mass spectrometry (LC-MS), although LC-MS analysis is more complicated to operate, exhibits poorer performance, and costs more .The scope of conventional GC-MS is limited owing to two main reasons:1. Relatively nonvolatile molecules (such as large polycyclic aromatic hydrocarbons) are incompatible with gas chromatography and especially incompatible with the mass spectrometer ion source. The ion source-limited temperature results in an early onset of chromatographic peak tailing.Address reprint requests to Professor Aviv Am irav, School of Chemistry, Sadder Faculty of Exact Sciences, Tel Aviv University, Ramat Aviv, Tel Aviv 69978, Israel.

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Electron impact mass spectrometry of alkanes in supersonic molecular beams

Cited by 61 publications

References 36 publications

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN

Fourier Transform-Ion Cyclotron Resonance-Mass Spectrometer as a New Tool for Organic Chemists

Fast, very fast, and ultra-fast gas chromatography-mass spectrometry of thermally labile steroids, carbamates, and drugs in supersonic molecular beams

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Electron impact mass spectrometry of alkanes in supersonic molecular beams

Cited by 61 publications

References 36 publications

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH3CN

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH3CN

Fourier Transform-Ion Cyclotron Resonance-Mass Spectrometer as a New Tool for Organic Chemists

Fast, very fast, and ultra-fast gas chromatography-mass spectrometry of thermally labile steroids, carbamates, and drugs in supersonic molecular beams

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Resources

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The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN

The First, General, Highly Efficient Method for Preparing Tetrasubstituted Epoxides Using HOF·CH₃CN