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Mass Spectrometry: Molecular Fragmentation Overview01:20

Mass Spectrometry: Molecular Fragmentation Overview

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The ionization of a molecule into a molecular ion inside the mass spectrometer causes instability in the molecule's structure due to the loss of an electron. This eventually leads to the fragmentation or breaking of some bonds in the molecule. The fragmentation occurs predominantly at specific bonds to yield relatively stable fragments.
One type of fragmentation pattern is the cleavage of a single bond in the molecular ion. The cleavage leads to a radical and a cation. The cleavage can...
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Mass Spectrometry: Alkene Fragmentation00:59

Mass Spectrometry: Alkene Fragmentation

2.5K
Alkenes lose one electron from the unsaturated π bond upon ionization and form stable molecular ions. Further fragmentation of alkenes occurs through three different reaction pathways. The most prominent fragmentation is the cleavage at the allylic position. The resultant allylic carbocation is resonance stabilized. In the mass spectra of terminal alkenes, this fragment appears at a mass-to-charge ratio of 41. In the internal alkenes, where there are two choices of allylic cleavage, the...
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Arrhenius Plots02:34

Arrhenius Plots

38.9K
The Arrhenius equation relates the activation energy and the rate constant, k, for chemical reactions. In the Arrhenius equation, k = Ae−Ea/RT, R is the ideal gas constant, which has a value of 8.314 J/mol·K, T is the temperature on the kelvin scale, Ea is the activation energy in J/mole, e is the constant 2.7183, and A is a constant called the frequency factor, which is related to the frequency of collisions and the orientation of the reacting molecules.
The Arrhenius equation can be used...
38.9K
Mass Spectrometry: Long-Chain Alkane Fragmentation01:18

Mass Spectrometry: Long-Chain Alkane Fragmentation

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The molecular ions of linear alkanes prefer to fragment at the carbon-carbon bond away from the end of the chain since the cleavage of an inner bond creates a stable carbocation and a stable radical. Consequently, the mass signals of linear alkanes feature intense peaks in the middle of the mass-to-charge ratio plot with weaker peaks on either end. The fragmentation of each carbon-carbon bond with the release of a methyl group in each splitting leads to prominent peaks in the mass spectra...
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Mass Spectrometry: Carboxylic Acid, Ester, and Amide Fragmentation01:01

Mass Spectrometry: Carboxylic Acid, Ester, and Amide Fragmentation

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The fragmentation patterns observed for compounds such as carboxylic acids, esters, and amides in the mass spectra include ⍺-cleavage and McLafferty rearrangement. Fragmentation by ⍺-cleavage preferentially occurs at the carbon-carbon bond at the ⍺-position next to the carboxylic group to generate a neutral radical and a cation. Long chain compounds with hydrogen at their γ-carbon undergo McLafferty rearrangement to give a radical cation and a neutral alkene.
For example,...
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Mass Spectrometry: Alkyl Halide Fragmentation01:22

Mass Spectrometry: Alkyl Halide Fragmentation

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Chlorine isotopes exist as 35Cl and 37Cl in a 3:1 ratio, while bromine isotopes exist as 79Br and 81Br in a 1:1 ratio. The mass spectrum of alkyl halides typically produces two distinct molecular ion peaks, the molecular ion peak, [M], and the molecular ion plus two, [M + 2] peak. The relative heights of these two peaks are proportional to the isotopic abundance ratios of the halide. For example, 2‐chloropropane and 1‐bromopropane display two peaks with relative peak heights in a 3:1 and...
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Related Experiment Video

Updated: Jun 13, 2025

Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers
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Coulomb Explosion Imaging as a Tool to Distinguish Between Stereoisomers

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Kohn-Sham fragment energy decomposition analysis.

Tommaso Giovannini1

  • 1Department of Physics, University of Rome Tor Vergata, Via della Ricerca Scientifica 1, 00133 Rome, Italy and Scuola Normale Superiore, Piazza dei Cavalieri 7, 56126 Pisa, Italy.

The Journal of Chemical Physics
|September 13, 2024
PubMed
Summary

We developed Kohn-Sham fragment localized molecular orbitals (KS-FLMOs) to analyze non-covalent interactions. This new method provides physical insights into molecular interactions in various environments.

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Area of Science:

  • Computational Chemistry
  • Quantum Chemistry
  • Theoretical Chemistry

Background:

  • Understanding non-covalent interactions is crucial in chemistry and biology.
  • Existing methods for analyzing these interactions can be computationally intensive or lack detailed physical insights.

Purpose of the Study:

  • To introduce a novel method for localizing molecular orbitals within fragments of a molecular system.
  • To develop a new energy decomposition analysis based on these localized orbitals.
  • To provide a tool for rationalizing non-covalent interactions in various chemical systems.

Main Methods:

  • Development of Kohn-Sham fragment localized molecular orbitals (KS-FLMOs) by minimizing local electronic energies and maximizing inter-fragment repulsion.
  • Application of KS-FLMOs to propose Kohn-Sham fragment energy decomposition analysis (KS-FDA).
  • Validation of KS-FDA against established energy decomposition analysis techniques and high-level computational calculations.

Main Results:

  • Successful localization of Kohn-Sham molecular orbitals within specific molecular fragments.
  • Demonstration of KS-FDA's capability to rationalize non-covalent interactions in systems both in vacuo and in solution.
  • Validation showing agreement with state-of-the-art methods and high-level calculations.

Conclusions:

  • KS-FLMOs provide a robust foundation for fragment-based electronic structure analysis.
  • KS-FDA offers a physically insightful approach to understanding non-covalent interactions.
  • The developed method holds promise for advancing the study of molecular interactions in complex systems.