posted on 2024-10-11, 14:37authored byChing-Han Chang, Pawel L. Urban
Electrospray ionization (ESI) remains the dominant technique
in
mass spectrometry (MS)-based analyses. Here, we investigated the relationship
between a crucial aspect of ESI, the formation of the Taylor cone,
and the MS ion current by utilizing a triple quadrupole (QqQ) mass
spectrometer coupled with a streaming high-speed camera and a 3-ring
electrode system. In one test, ion current over a 30-s plume gate
(a ring electrode) opening was compared with the Taylor cone occurrence
analyzed offline, with Spearman’s correlation coefficients
consistently near 0 despite parameter variations. In another test,
real-time detection of Taylor cones was synchronized with QqQ-MS,
selectively opening (de-energizing) the plume gate based on the Taylor
cone status. This approach enabled matching the ion current with the
Taylor cone occurrence. There was no apparent difference between the
MS signals recorded in the presence and absence of a Taylor cone.
Additionally, a Faraday plate was employed as a detector in offline
experiments, revealing agreement between the frequency of liquid meniscus
(Taylor cone) oscillation (∼1.92 kHz)measured by high-speed
imagingand the frequency of spray current (∼1.93 kHz).
We suggest that the lack of positive correlations in the MS experiments
is due to intrinsic ion carryover during transit from the ion source
to the detector and due to the insufficient data acquisition rate
of the mass spectrometer, which erases short-term fluctuations of
ion current.