AI Article Synopsis
- MALDI-generated [M + Ag](+) ions from cyclic and linear polystyrenes and polybutadienes exhibit distinct fragmentation patterns in tandem mass spectrometry (MS(2)).
- Fragmentation in both structures begins with homolytic cleavage of C-C bonds, but linear polymers undergo extensive depolymerization, resulting in low-mass radical ions, while cyclic polymers have reduced depolymerization due to H-atom transfer.
- The differences in fragmentation lead to varying fragment ion distributions, allowing researchers to determine macromolecular architecture and identify specific end groups or linkers used in the polymers.
Article Abstract
[M + Ag](+) ions from cyclic and linear polystyrenes and polybutadienes, formed by matrix-assisted laser desorption ionization (MALDI), give rise to significantly different fragmentation patterns in tandem mass spectrometry (MS(2)) experiments. In both cases, fragmentation starts with homolytic cleavage at the weakest bond, usually a C-C bond, to generate two radicals. From linear structures, the separated radicals depolymerize extensively by monomer losses and backbiting rearrangements, leading to low-mass radical ions and much less abundant medium- and high-mass closed-shell fragments that contain one of the original end groups, along with internal fragments. With cyclic structures, depolymerization is less efficient, as it can readily be terminated by intramolecular H-atom transfer between the still interconnected radical sites (disproportionation). These differences in fragmentation reactivity result in substantially different fragment ion distributions in the MS(2) spectra. Simple inspection of the relative intensities of low- versus high-mass fragments permits conclusive determination of the macromolecular architecture, while full spectral interpretation reveals the individual end groups of linear polymers or the identity of the linker used to form the cyclic polymer.
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