posted on 2021-02-19, 22:43authored byZhaoyu Zheng, Athula B. Attygalle
According
to current consensus, structures of protomeric (or deprotomeric)
tautomers of gaseous ions generated by electrospray ionization depend
primarily on the nature of the spray solvent. To probe the effect
of the spray solvent on protonation, 4-aminobenzoic acid (PABA) has
often been selected as the model compound. It is widely accepted that
the protonation in the gas phase takes place primarily on the carbonyl
oxygen atom when the sample is sprayed in methanol and on the nitrogen
atom when acetonitrile is used as the spray solvent. Although this
observation is valid, our current results indicate that the determination
of the predominant protomer in the gas phase by the spray solvent
is an indirect effect moderated by the solvent vapor molecules present
in the ambient ion source. To investigate real-time changes in protomer
distributions due to solvents, we used ion-mobility mass spectrometry
(IM-MS). Initially, when a PABA solution in methanol was electrosprayed,
the ion-mobility arrival-time profile recorded showed essentially
one peak for the O-protomer. However, when acetonitrile
or acetone vapors were introduced to the ambient-pressure
ion source via the flowing desolvation gas, the intensity of the O-protomer peak diminished rapidly, and the N-protomer signal became dominant. The moment the acetonitrile (or
acetone) vapors were removed from the ion source, the protomer-distribution
signals began gradually reverting back to their original intensities.
Furthermore, when PABA samples in methanol and acetonitrile were electrosprayed
separately via a dual-sprayer setup, which allowed for the selective
blocking of the gaseous ion-generation cascade of charged droplets
from either sprayer, the predominant signal corresponded only to the N-protomer, irrespective of the position of the mechanical
barrier. Because the mechanical barrier prevents only the gaseous
ion formation, but not the physical access of solvent vapors to the ion source, it is evident
that the solvent vapor that engulfs the ion source is the governing
factor that decides the protomer distribution, not the nature of the
spray solvent. Noticeably, acetonitrile wields a stronger effect on
the manifested protomer distribution than many other solvents, including
methanol, water, hexanes, and toluene. Apparently, the so-called “memory”
of the solution-phase structures and the phenomenon described as “kinetic
trapping” are both due to indirect effects caused by the solvent
vapor engulfing the atmospheric-pressure ion source. Moreover, the
so-called “memory” effect can either be “saved”
or “erased” by exposing the initially formed gaseous
ions to different solvent vapors from an alternative source.