Specific Process Knowledge/Characterization/Stylus Profiler Measurement Uncertainty: Difference between revisions
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==Total Uncertainty for steps < 1 µm== | ==Total Uncertainty for steps < 1 µm== | ||
Apart from the uncertainty described above, the underlying "shape" of the scan due to the instrument itself will influence the measurement accuracy for steps <1 µm. Although the stylus profilers use an optically flat surface as a reference, the basic underlying scan is never truly completely flat. We have in June 2025 found both random and repeatable scan bowing / noise in the range of 10-60 nm across a 2 cm (2000 µm) scan. This is enough to influence the measurement accuracy of steps <1 µm and especially <500 nm. | |||
We therefore cannot recommend using the stylus profilers for measuring steps <100 nm | We therefore cannot recommend using the stylus profilers for measuring steps <100 nm and one must expect relatively large uncertainty on small steps < 1 µm. | ||
[[image:Si 6 in left_50umprsec_aveof2.png||right|thumb|Sample average of 2 scans of a blank, new 6" Si wafer made with the P17 Stylus Profiler.]] | |||
[[image:BlankSi 6in center-2-altlevel2.PNG||right|thumb|Sample scan of a blank, new 6" Si wafer made with the DektakXT Stylus Profiler.]] | |||
If measuring steps <100 nm it is important to check a measurement of a "flat" area nearby and to play with positioning the measured step in different locations along the scan length (to show variation in the underlying scan noise right under the step). | If measuring steps <100 nm it is important to check a measurement of a "flat" area nearby and to play with positioning the measured step in different locations along the scan length (to show variation in the underlying scan noise right under the step). | ||
The figures on the right show representative "flat" scans made with the P17 and DektakXT. The shape is influenced a lot by the position of the leveling cursors and a bow-like shape as the one seen in the P17 scan can easily be found in DektakXT scans of flat surfaces as well. More "flat" scans for the Dektak and P17 can be seen here: [[:File:Dektak XT and P17 scan flatness comparison summer 2025.pptx]]. | |||
===How much flatness can we expect of a "flat" scan?=== | |||
KLA, the manufacturer of the P17 profiler, provides some information on the flatness one can expect from the scans, some of which is freely available in [https://www.kla.com/wp-content/uploads/KLA_AppNote_Stylus_2D_Stress.pdf this document]. Here we see that we can expect a variation of up to 40 nm across a flat scan of 3 cm. Thus the variation of up to 40 nm across 2 cm that we have seen in practice is not far beyond the presumably best-case scenario stated by the manufacturer (our tool could use some lubrication of the scan axes at the time of measurement). | |||
For the P17 the underlying scan noise or bow is extremely reproducible for many scans in the same position whether or not the vacuum hold is turned on. Therefore it seems that the non-flatness of the scans derive from some underlying structure on the optically flat surface or the scan rails. | |||
For the Dektaks, we have in some cases seen that the scan noise is reproducible not only for scans in the same location, but even for scans in different locations on the stage, which must be due to some kind of dirt on the "feet" of the stage as they move across the optical flat. However in other cases, as in all the scans shown in the document above, the bowing of the scan varies even though the scan coordinates and sample are the same. The latter might be because the stage positioning is a little less accurate than for the P17 or because there is more environmental noise influencing the measurement. | |||
The | ===How does the underlying scan noise affect the measurement accuracy=== | ||
The step determination will usually be better than the noise of the underlying scan - we don't expect an error in the measured step sizes as big as 30-60 nm. This comes down to removing some of the noise due to averaging parts of the scan during leveling and measuring. | |||
For the | For example, in the DektakXT we regularly measure shadow masked metal films made by e-beam evaporation that are around 100 nm thick. We have found good agreement between the DektakXT measurements of a 500 µm wide step and XRR measurements of films of the same thickness, so we see no reason not to trust these measurements to within around +/- 5 nm. We level the scan with the leveling cursors close to the step before and after it, so only the scan noise in an ~700 µm range is important. Additionally, since we average the thickness across approx. 400 µm at the top of the step compared to the ~40 µm leveling intervals nearby (where the height is also averaged), the variation comes out much smaller than what is seen across a full 2000 µm scan. | ||
In practice we have found the step heights around 100 nm can be measured with higher accuracy in the DektakXT than the P17: We tend to get a measurement with the DektakXT within a few nm of the XRR measurement while the measurement with the P17 has been off by around 10-15 nm. We don't yet have a good explanation for this - nor do we have enough data to prove it's a general trend. | |||
It may be even better to just level with cursors near each other on what one knows is a flat surface and then measure just before and after the step very near the leveling cursors to get the best height estimate. | |||