High pressure chemistry in a Fourier transform ion cyclotron resonance mass spectrometer using a split-pair magnet

A new experimental method has been developed to probe ion/molecule reactions at gas pressures up to 0. 1 torr. A Fourier transform ion cyclotron resonance (FTICR) mass spectrometer has been constructed to trap ions within the trapped ion cell at these pressures for time intervals up to several hundred milliseconds, allowing the ions to undergo several million collisions. Multiple pulsed valves inject the gaseous reagents in brief, high pressure bursts. A unique, high conductance vacuum chamber rapidly reduces the gas pressure from as high as 0.01 torr to near background pressures in 2–5 s for optimum operation of the FTICR for identifying the ionic products. A pressure of 0.1 torr is attainable but results in slower gas evacuation. High pressure operation of this instrument is demonstrated for ion chemistry in silane, argon, and silicon tetrafluoride. Pressures are sufficiently high to allow termolecular formation of adducts with the trapped ion cell. Negative ion formation in silane has greatly improved efficiency due to the high pressure ionization. Trace impurities at the ppm level in argon and silicon tetrafluoride are detected through chemical ionization afforded by the large number of ion/molecule collisions.