Sd. Tanner et al., REDUCTION OF SPACE-CHARGE EFFECTS USING A 3-APERTURE GAS-DYNAMIC VACUUM INTERFACE FOR INDUCTIVELY-COUPLED PLASMA-MASS SPECTROMETRY, Applied spectroscopy, 48(11), 1994, pp. 1367-1372
A three-aperture gas dynamic vacuum interface for ICP-MS has been deve
loped which reduces the ion current within the ion optics. The effect
on performance limitations previously associated with space charge wer
e determined. The gas and ion dynamics within the first stage of the v
acuum interface are similar to those of current ICP-MS instruments and
allow delineation of the relative effects of space charge in the inte
rface region and within the ion optics. The sensitivity of the instrum
ent to trace elements is similar to that of current commercial instrum
ents. The instrument shows an improvement in the discrimination agains
t low mass ion transmission. It also shows a dramatic improvement in b
oth the magnitude and analyte-ion mass dependence of the signal suppre
ssion induced by a high concentration of a heavy concomitant element (
Tl). The new design results in more uniform ion kinetic energies as a
function of ion mass-to-charge ratio. The performance improvements are
ascribed to the reduction of space charge effects resulting from both
the reduction of the ion current within the ion optics and the reduct
ion of the mass dependence of the ion kinetic energies. It is conclude
d that the discrimination against low-mass ions and the magnitude and
analyte mass dependence of the signal suppression induced by concomita
nt heavy elements observed with current ICP-MS instruments derive from
space charge effects within the ion optics. These effects are less si
gnificant within the first stage of the vacuum interface or within the
mass analyzer.