Analysis of VX on Soil Particles Using Ion Trap Secondary Ion Mass Spectrometry

Abstract

The direct detection of the nerve agent VX (methylphosphonothioic acid, S-[2-[bis(1-methylethyl)amino]ethyl] O-ethyl ester) on milligram quantities of soil particles has been achieved using ion trap secondary ion mass spectrometry (IT-SIMS). VX is highly adsorptive toward a wide variety of surfaces; this attribute makes detection using gas-phase approaches difficult but renders the compound very amenable to surface detection. An ion trap mass spectrometer, modified to perform SIMS, was employed in the present study. A primary ion beam (ReO₄^-) was fired on axis through the ion trap, where it impacted the soil particle samples. [VX + H]⁺, [VX + H]⁺ fragment ions, and ions from the chemical background were sputtered into the gas-phase environment of the ion trap, where they were either scanned out or isolated and fragmented (MS²). At a surface concentration of 0.4 monolayer, intact [VX + H]⁺, and its fragment ions, were readily observable above background. However, at lower concentrations, the secondary ion signal from VX became obscured by ions derived from the chemical background on the surface of the soil particles. MS² analysis using the ion trap was employed to improve detection of lower concentrations of VX: detection of the ³⁴S isotopic ion of [VX + H]⁺, present at a surface concentration of ∼0.002 monolayer, was accomplished. The study afforded the opportunity to investigate the fragmentation chemistry of VX. Semiempirical calculations suggest strongly that the molecule is protonated at the N atom. Deuterium labeling showed that formation of the base peak ion (C₂H₄)N(i-C₃H₇)₂⁺ involves transfer of the amino proton to the phosphonothioate moiety prior to, or concurrent with, C−S bond cleavage. To manage the risk associated with working with the compound, the vacuum unit of the IT-SIMS was located in a hood, connected by cables to the externally located electronics and computer.