Determination of residence times of ions in a resistive glass selected ion flow‐drift tube using the Hadamard transformation

Rationale Selected ion flow tube mass spectrometry, SIFT‐MS, used for trace gas analyses has certain fundamental limitations that could be alleviated by adding a facility that allows reaction times and ion interaction energies to be varied. Thus, a selected ion flow‐drift tube, SIFDT, has been created to explore the influence of an embedded electric field on these parameters and on reaction processes. Methods The new SIFTD instrument was constructed using a miniature resistive glass drift tube. Arrival times of ions, t , analysed by a downstream quadrupole mass spectrometer over the m/z range 10–100 were studied by modulating the injected ion current using a gate lens. Single pulse modulation was compared with pseudorandom time multiplexing exploiting the Hadamard transformation. A simple model involving analysis of ethanol and water vapour mixture in air was used to explore the advantages of the SIFDT concept to SIFT‐MS analysis. Results It is shown that the resistive glass drift tube is suitable for SIFDT experiments. The Hadamard transformation can be used to routinely determine reagent ion residence time in the flow‐drift tube and also to observe differences in arrival times for different product ions. Two‐dimensional data combining arrival time and mass spectra can be obtained rapidly. The calculated ion drift velocities vary with the reduced field strength, E/N , and the calculated ion mobilities agree with theoretical and previous literature values. Conclusions This study has provided evidence that the SIFDT‐MS technique can be implemented in a miniature and low‐cost instrument and two‐ or three‐dimensional data can be obtained (product ion count rates as functions of m/z , t and E/N ) using the Hadamard transformation thus providing exciting possibilities for further analytical additions and extensions of the SIFT‐MS technique. Copyright © 2015 John Wiley & Sons, Ltd.