Continuum source atomic absorption

Continuum source atomic absorption spectrometry (CS-AAS) approach. The instability of the most intense continuum
has long appealed to the spectroscopic community because of sources, xenon arc lamps, gives noisy baselines and poor
the potential for simultaneous multi-element AAS determi- detection limits. Medium resolution monochromators, that are
nations, a shortcoming of conventional line source AAS ideal for isolating HCL emission lines, provide a spectral
(LS-AAS). Unfortunately, owing to limitations of the source, bandwidth that is too large for use with a continuum source.
CS-AAS has failed for many years to compete with LS-AAS The large spectral bandwidth results in poor sensitivity and
with respect to detection limits. Today, with the high radiation specificity, non-linear calibration curves and greater susceptithroughput
and spectral resolution of e´chelle spectrometers, bility to broadband background interferences. In addition, the
the multi-wavelength detection capability, low read noise and intensity of most continuum sources decreases dramatically
high quantum efficiency of charge coupled detectors (CCDs) below 280 nm. Consequently, the use of a continuum source
and the high speed data acquisition capabilities of modern for AAS requires the redesign of the whole instrument.
computers, CS-AAS has surpassed the analytical capabilities As shown in Table 1, a variety of instrumental designs have
of LS-AAS. These advantages will be explained in detail in been explored for CS-AAS. The three main challenges were
this review. Although it takes time for the implementation of to obtain sensitivities, detection limits and calibration ranges
new concepts, especially when it requires a considerable capital comparable to LS-AAS. Sensitivity was initially enhanced by
investment, CS-AAS appears ripe for development. It seems the use of multipass absorption cells.3,4 It soon became obvilikely
that if AAS was being developed today for the first ous, however, that the best approach to recovering the lost
time, it would be with a continuum source. sensitivity was the use of a high resolution spectrometer
AAS, as first described by Walsh1 and Alkemade and (interferometers and e´chelles)7–14 to provide the narrow analyt-
Milatz,2 derived its success from the use of hollow cathode ical bandwidth previously supplied by the HCL. Obtaining
lamps (HCLs) as the radiation source. These lamps, with their detection limits equal to those for LS-AAS required minimizing
stable and narrow emission lines, offered high analyte speci- the flicker noise of the xenon arc lamp. This was accomplished
ficity, excellent detection limits (for the time) and linear using wavelength modulation with phase sensitive deteccalibration
curves (2.5–3.0 orders of magnitude of concen- tion.5–7,10–14 Wavelength modulation has been implemented
tration). Unfortunately, these lamps are not suitable as multi- using quartz refractor plates,5,6,10,11 oscillating e´talons7 and,
element sources. Multi-element HCLs are restricted to compat- ultimately, array detectors.12–14 The linearity of the calibration
ible elements and are always less intense than the single- curves is determined primarily by the spectral bandwidth of
element lamps. Combinations of single- and multi-element the analytical measurement. Thus, the e´chelles and interfer-
HCLs suffer from loss of intensity due to the necessary beam ometers have provided the best linearity,8,10 although the
splitters/combiners. Consequently, although AAS is a powerful oscillating e´talon produced an unusual, multi-humped calianalytical
tool, it has always remained a single-element bration curve owing to the narrowness of the spectral bandtechnique.
pass. It should be noted that all the instruments described in
Table 1, with one exception, are single-element designs. The
†Presented at the Ninth Biennial National Atomic Spectroscopy only functional, multi-element instrument was that described
Symposium (BNASS), Bath, UK, July 8–10, 1998. by Harnly et al.11 in 1979.