Melanie J. Waltman scite author profile

In an effort to better understand the formation of negative reactant ions in air produced by an atmospheric pressure corona discharge source, the neutral vapors generated by the corona were introduced in varying amounts into the ionization region of an ion mobility spectrometer/mass spectrometer containing a 63 Ni ionization source. With no discharge gas the predominant ions were O 2 − , however, upon the introduction of low levels of discharge gas the NO 2 − ion quickly became the dominant species. As the amount of discharge gas increased the appearance of CO 3 − was observed followed by the appearance of NO 3 − . At very high levels, NO 3 − species became effectively the only ion present and appeared as two peaks in the IMS spectrum, NO 3 − and the NO 3 − ·HNO 3 adduct, with separate mobilities. Since explosive compounds typically ionize in the presence of negative reactant ions, the ionization of an explosive, RDX, was examined in order to investigate the ionization properties with these three primary ions. It was found that RDX forms a strong adduct with both NO 2 − and NO 3 − with reduced mobility values of 1.49 and 1.44 cm 2 V −1 s −1 , respectively. No adduct was observed for RDX with CO 3 − although this adduct has been observed with a corona discharge mass spectrometer. It is believed that this adduct, although formed, does not have a sufficiently long lifetime (greater than 10 ms) to be observed in an ion mobility spectrometer.

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Characterization of Triacetone Triperoxide by Ion Mobility Spectrometry and Mass Spectrometry Following Atmospheric Pressure Chemical Ionization

Ewing

Waltman

Atkinson

2011

Anal. Chem.

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The atmospheric pressure chemical ionization of triacetone triperoxide (TATP) with subsequent separation and detection by ion mobility spectrometry has been studied. Positive ionization with hydronium reactant ions produced only fragments of the TATP molecule, with m/z 91 ion being the most predominant species. Ionization with ammonium reactant ions produced a molecular adduct at m/z 240. The reduced mobility value of this ion was constant at 1.36 cm(2)V(-1)s(-1) across the temperature range from 60 to 140 °C. The stability of this ion was temperature dependent and did not exist at temperatures above 140 °C, where only fragment ions were observed. The introduction of ammonia vapors with TATP resulted in the formation of m/z 58 ion. As the concentration of ammonia increased, this smaller ion appeared to dominate the spectra and the TATP-ammonium adduct decreased in intensity. The ion at m/z 58 has been noted by several research groups upon using ammonia reagents in chemical ionization, but the identity was unknown. Evidence presented here supports the formation of protonated 2-propanimine. A proposed mechanism involves the addition of ammonia to the TATP-ammonium adduct followed by an elimination reaction. A similar mechanism involving the chemical ionization of acetone with excess ammonia also showed the formation of m/z 58 ion. TATP vapors from a solid sample were detected with a hand-held ion mobility spectrometer operated at room temperature. The TATP-ammonium molecular adduct was observed in the presence of ammonia and TATP vapors with this spectrometer.

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Melanie J. Waltman

The vapor pressures of explosives

Characterization of a distributed plasma ionization source (DPIS) for ion mobility spectrometry and mass spectrometry

Mechanisms for negative reactant ion formation in an atmospheric pressure corona discharge

Characterization of Triacetone Triperoxide by Ion Mobility Spectrometry and Mass Spectrometry Following Atmospheric Pressure Chemical Ionization

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