Issue 1, 2022

A multifaceted approach towards understanding the peculiar behavior of (α)-hydroxyiminophosphonates

Abstract

The peculiar isomer-selective reduction of (α)-hydroxyiminophosphonates (oxime isomers) into (α)-hydroxyaminophosphonate (hydroxylamine) derivatives is presented. A library of 16 (α)-hydroxyiminophosphonates is prepared and studied via a unique multifaceted approach involving the interplay of NMR, XRD, MS, IM-MS and computational chemistry techniques. The combination of NMR, XRD and HPLC enables the seamless separation, identification and quantification of the oxime isomers (E/Z). Tandem MS (MS/MS) enables the determination of the fragmentation patterns for both isomers. Collision energy breakdown curves highlight the order of apparition of the fragments as well as their related energy of fragmentation, demonstrating that the strength of the C–P bond in the Z isomers is much weaker than in the E isomers. Computational chemistry demonstrates that favorable protonation site is isomer-dependent with the phosphonate moiety being the favorable protonation site for the E isomers, while protonation occurs preferentially on the amino moiety for Z isomers regardless of the phosphite source. The combination of these various methods led an unprecedented level of characterization of oxime isomers, providing a better uderstanding of the isomer-dependent behavior of (α)-hydroxyiminophosphonates.

Graphical abstract: A multifaceted approach towards understanding the peculiar behavior of (α)-hydroxyiminophosphonates

Supplementary files

Article information

Article type
Research Article
Submitted
17 Oct 2021
Accepted
19 Nov 2021
First published
22 Nov 2021

Org. Chem. Front., 2022,9, 173-182

A multifaceted approach towards understanding the peculiar behavior of (α)-hydroxyiminophosphonates

T. Toupy, C. Kune, K. Van Hecke, L. Quinton and J. M. Monbaliu, Org. Chem. Front., 2022, 9, 173 DOI: 10.1039/D1QO01564H

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