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Comparison of EDS and WDS
Using EDS, all of the energies of
the characteristic X-rays incident on the detector are measured
simultaneously and data acquisition is therefore very rapid across the
entire spectrum. However, the resolution of an EDS detector is considerably
worse than that of a WDS spectrometer.
The WDS spectrometer can acquire
the high count rate of X-rays produced at high beam currents, because it
measures a single wavelength at a time. This is important for trace element
analysis. The resolution of the EDS detector is such that situations may
arise in which overlap of adjacent peaks becomes a problem. Many of the
overlaps can be handled through deconvolution of the peaks. Others, however,
are more difficult, particularly if there is only a small amount of one of
the overlapped elements. Examples of these more difficult overlap situations
are listed in Table 2.
| Common Peak Overlaps in EDS Microanalysis |
| S Kα - Mo Lα − Pb Mα |
| Na Kα - Zn Lα |
| Ni Lα - La Mα |
| Zr Lα - Pt Mα - P Kα - Ir Mα |
| Nb Lα - Hg Mα |
| Si Kα - W Mα − Ta Mα - Rb Lα |
| Al Kα - Br Lα |
| Y Lα- Os Mα |
| O Kα - V Lα |
| Mn Lα - Fe Lα - F Kα |
Table 2: Common peak overlaps in microanalysis
In practice it is
advantageous to use the speed of EDS for an initial survey of an unknown
sample because major elements will be rapidly identified. However, if trace
elements are present they will not be identified, and it may be difficult to
interpret complex overlaps. Following the initial ED survey, WD can be used
to check for overlaps and to increase sensitivity for trace elements.
Resolution
comparison between EDS and WDS
The following two examples show
how the improved resolution of WDS make peak identification easy.
MoS2
The WD spectrum for MoS2 has been
acquired from the INCAWave spectrometer using INCAEnergy+ software. Using
this application, the WD spectrum acquisition is initiated by highlighting
part of the ED spectrum. The two spectra are then superimposed automatically
to illustrate the difference in resolution. In the yellow ED spectrum (fig.
4), the molybdenum Lα line at 2.293 keV is severely overlapped by sulfur Kα
at 2.307 keV, but the WD spectrum (in blue) clearly resolves these lines and
SKβ and MoLβ.
Si, Nb,
Mo, W Containing Precipitates
Sub-micron precipitates in an
alloy sample require analysis at relatively low beam voltages to eliminate
possible X-ray contribution from surrounding phases. This means that L lines
for tungsten (8.3977 keV) which are clearly visible in the ED spectrum, are
not efficiently excited and so are unsuitable for characterizing
composition. In such circumstances, the M-lines of W must be used. Since the
M lines for W are not resolvable from Si K lines by EDS in this case (WMα at
1.774 keV and Si Kα at 1.740 keV), the use of WDS is preferred. The spectra
in Fig. 5 illustrate this point. Again, INCAEnergy+ was used to obtain a WD
spectrum overlaid on the ED spectrum (scaled to the WD spectrum). The
presence of tungsten in the ED spectrum is masked by the Si K lines while
the two are clearly distinguishable in the WD spectrum.
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