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1. Investigation of Unusual N -(Triphenyl-λ 5 -phosphanylidene) Amide Fragmentation Observed upon MS/MS Collision-Induced Dissociation.

Author

Kurmi M, Kadambar VK, Srinivas P, Reddi Y, Panda M, Peddicord M, Miller SA, Young J, Bhutani H, and Bajpai L

Abstract

A mechanism of unusual tandem (MS/MS) fragmentation of protonated species of N -(triphenyl-λ 5 -phosphanylidene) derivatives, [M + H] + to generate triphenylphosphine oxide (TPPO) within the mass spectrometer has been investigated and reported. Collision-induced dissociation of these molecules resulted in the generation of TPPO as a signature fragment. This fragment suggested the presence of a P-O bond in the structure which was contrary to the structure of the compound identified by nuclear magnetic resonance spectrometry (NMR) and single-crystal X-ray diffractometry (SXRD) techniques with a P═N bond rather than a P-O bond. In order to confirm the generation of the TPPO fragment within the mass spectrometer, 14 different N -(triphenyl-λ 5 -phosphanylidene) derivatives containing amide, 18 O-labeled amide, thiamide, and nonacyl phosphazene derivatives were synthesized and their MS/MS behavior was studied by liquid chromatography-high-resolution mass spectrometry. Fragmentation of these amide derivatives generated TPPO/TPPS or their 18 O-labeled analogues as the major fragment in almost all cases under similar MS conditions. Based on the outcome of these experiments, a plausible mechanism for such fragmentation, involving the intramolecular shifting of oxygen from carbon to phosphorus, has been proposed. DFT calculations for the protonated species at B3LYP-D3/6-31+G(d,p) further supported the proposed mechanism involving a four-membered ring, P-O-C-N, as the transition state. Details of this work are presented here.

Published

2023