Specific Process Knowledge/Characterization/Profiler
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Overview of the Nanolab profilers
All the profilers are compared on the topographic measurement page.
The sections below describe each profiler (stylus profilers and optical profilers) in more detail.
Dektak XTA stylus profiler
The Dektak XTA stylus profiler from Brüker is used for profiling surfaces of samples with structures in the micro- and nanometer range. The size of the structures that can be measured is limited by the tip dimensions.
A profile measurement can be done across a specific structure by using a high magnification camera to locate the structure. It is also possible to program the stylus to measure in several positions, defined with respect to some deskew points. Stress measurements of thin films can be done by measuring the wafer bow.
The user manual, quality control procedure and results, technical information and contact information can be found in LabManager:
| Purpose | Profiler for measuring micro structures |
|
|---|---|---|
| Performance | Scan range x y |
Line scan x: 50 µm to 55 mm in a single scan, up to 200 mm with stiching |
| Scan range z |
50 Å to 1 mm | |
| Resolution x y |
Down to 0.003 µm in theory, but in practice limited by the 5 µm radius of the tip | |
| Resolution z |
1 Å, 10 Å, 80 Å or 160 Å (for ranges 65 kÅ, 655 kÅ, 5240 kÅ and 1 mm respectively) | |
| Height accuracy z (95 % confidence) |
For very well defined steps ~ 2 % for a 1 µm step and ~ 1 % for a 25 µm step (see below) | |
| Max scan depth as a function of trench width W |
1.2*(W[µm]-5µm) | |
| Hardware settings | Tip radius |
|
| Substrates | Substrate size |
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| Substrate materials allowed |
|
Height measurement accuracy
The accuracy of a height measurement with the profiler depends on the measurement settings, the sample, the instrument calibration and the resolution.
Use the right measurement settings for your sample
Both the force setting and the scan speed are important: Too high force may compress a soft material like Al, Au or some polymers, while too low force may lead to the stylus "jumping" over features, especially if the scan speed is high. Too low scan speed may result in drift of the measurement and lots of noise while too high scan speed like low force may mean that the stylus tip does not have time to reach the bottom of the features you are measuring (see the DektakXT manual, Figure 3 for details).
A sharp vertical step is easiest to measure. If the step is gradual or the surface is very rough, it can be difficult to determine where to measure and how the scan should be leveled.
Influence of calibration standard uncertainty
Nanolab staff check the instrument's measurement accuracy with a standard step height of 917 nm for the three smaller ranges and 24.925 µm for the three ranges, so that the two middle ranges are checked with both standards. The 95 % confidence intervals for the standards are 17 nm for the 917 nm standard and 0.072 µm for the 24.925 µm standard. If the control measurement is beyond the limit set in our Quality Control procedure, the instrument is calibrated and the users informed (see LabManager for details on the control instruction and the control measurement data).
All this means that the 95 % confidence interval of a 1 µm step measured with the 6.5 kÅ range is at least the 1.8 % error of the standard step while the 95 % confidence interval of a 25 µm step measured with the largest range is at least on the order of the 0.29 % error of the standard step. Steps between 1 and 25 µm measured with the intermediate ranges will presumably have an intermediate error just due to the calibration uncertainty while the calibration-related uncertainty is presumably larger percentagewise for smaller or larger steps.
Total uncertainty
Apart from the error due to the calibration standard's uncertainty, there will be random noise in any measurement, which we have found for many repeated measurements of the standard step height (a rigid, well defined vertical step) is on the order of ± 5 nm. There is also a tiny contribution to the error from the instrument's resolution and a small but significant contribution from the spread of values that the Dektak actually measures compared to the theoretical height of the standard step height.
To estimate the overall accuracy of the Dektak's measurements you can convolute the various sources of error. This is shown graphically on the right. You can see an uncertainty budget for the Dektak measurements here (made by Rebecca Ettlinger): Media:uncertainty budget Dektak rev.xlsx. It is based on the assumption that all the error sources are independent and can therefore be added by the sum of squares method. The resulting error calculation for a 1 micron very well defined standard step is about 2 % (as the uncertainty on the calibration standard dominates), while for a very well defined step of 25 microns the cumulative error is about 0.7-1 %. These are the uncertainties listed in the table. However, in real devices the random error will often be much larger than for our standard samples and so the real confidence interval will be larger.
To improve the accuracy of your particular measurement, you should repeat the measurement several times and estimate the standard deviation. If the scatter is quite small you can try to include the calibration error as a percentage of the step height in your estimate of the total error. If the scatter of your measurements is large that will probably be the dominant source of error in your measurement.
Stylus Profiler (Tencor P17)
The P17 Stylus Profiler from KLA Tencor is used in a similar manner to the Dektak XTA for profiling surfaces with structures in the micro- and submicrometer range as well as for measuring stress. Compared to the DektakXT, the P17 has more advanced options for stress measurements and allows the user to measure a stress map with up to 5° radial resolution. Programming a sequence of predefined scans in fixed locations on a wafer is also somewhat easier and the manual for doing it much better for the P17 than for the Dektak XTA. A disadvantage of the P17 is that is can be hard to locate structures as the maximum field of view of the camera is 1x1.5 mm. We recommend having a map of the sample design available so you can easily locate the features of interest. Otherwise the P17 is easy to use, fast, and accurate, just like the DektakXT.
The user manual, quality control procedure and results, technical information and contact information can be found in LabManager:
Info about using the analysis software from outside the cleanroom:
Apex software access
Acceptance test
- Acceptance measurements on the P17: Media:Appendix 3 Acceptance test p17 final_v2_Completed.pdf
- Vendor's own conformity test results after installation: File:Acceptance P17 ctd results.pdf
| Purpose | Profiler for measuring microstructures |
|
|---|---|---|
| Performance | Scan range X Y |
Line scan X: 20 µm to 200 mm in a single scan. No stitching. Map scan XY: In principle any rectangle that can be inscribed in a 200 mm circle, but resolution is limited to max. 4 million points and scanning is slow. In practice to get good resolution scan a very small area (e.g., 100 x 500 µm) |
| Scan range Z |
50 nm to 900 µm. It is possible to measure smaller steps but not recommended as the results may not be accurate. | |
| Resolution X Y |
Down to 0.025 µm in theory, but the tip radius is 2 µm, so the meaningful resolution is at the same order of magnitude | |
| Resolution Z |
0.01 Å, 0.08 Å, or 0.6 Å according to the manufacturer for ranges 13 µm, 131 µm, and 1 mm.† | |
| Height accuracy z (95 % confidence) |
~ 2 % for the smallest range for a 1 micron step and ~ 1 % for a 25 micron step for well-defined steps that are easy to measure, see section above. | |
| Max scan depth as a function of trench width W |
0.87*(W[µm]-2µm) = tan(60o)/2*(W[µm]-2µm) (empirically validated by Nanolab staff) | |
| Hardware settings | Tip radius |
|
| Substrates | Substrate size |
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| Substrate materials allowed |
|
†The resolution for the smallest range is theoretical, as this is below the noise threshold at least in our lab.
Height measurement accuracy for the Tencor P17 Stylus Profiler
This is similar to what applies to the DektakXT as described above. The P17 has slightly better reproducibility but as the uncertainty for small steps is dominated by the uncertainty on the standard step height's actual size, this does not make much difference. Just as for the Dektak, the reproducibility of your own measurements of your particular step can make a relatively large contribution to the total uncertainty, Steps in real devices are not always as easy to measure or as well defined as our standard step height measurements.
Optical Profiler (Sensofar S Neox)
The Sensofar S Neox 3D Optical Profiler has a sensor head that combines confocal, interferometry and focus variation techniques as well as thick and thin film measurement capabilities.
The Neox sensor head provides standard microscope imaging, confocal imaging, confocal profiling, PSI (Phase Shift Interferometry), CSI (Coherence Scanning Interferometry), Active illumination (Ai) Focus Variation and high resolution thin film thickness measurements on a single instrument.
The main purpose is 3D topographic imaging of surfaces, step height measurements in smaller trenches/holes than can be obtained with standard stylus methods (i.e. with aspect ratios higher that 1:1), roughness measurements with larger FOV (Field Of View) than the AFM, but less horisontal resolution.
For most samples the optical profiler provides fast and easy information without any sample preparation. However, it can be necessary to cover thin transparent layers (< 2 µm) with a thin layer of metal.
The resolution is limited by the objectives and the pixel resolution.
Analysis software:
- Free analysis software for visualizing and analyzing AFM and Optical profiler files (Sensofar) Gwyddion
- SensoView software from Sensfar want also be downloaded for all users: U:\Nlab\CleanroomDrive\_Equipment\Optical profiler Sensofar\SensoVIEW 1.6.0
The user manual, technical information (SensoSCAN and SensoVIEW manuals) and contact information can be found in LabManager:
Optical profiler (Sensofar S Neox) info page in LabManager
Process Information
- Sensofar presentation on how the sensofar works (for the previous system but the techniques are the same)
- S Neox leaflet including specifications
- Results from the Optical Profiler (Sensofar) acceptance test - for the previous system - expired!!
- Acceptance measurements on the S Neox Sensofar: Media:Acceptance measurements on Nanolab samples.pdf
| Equipment | Optical profiler | |
|---|---|---|
| Purpose | 3D topographic imaging of surfaces. |
|
| Posibilities | Confocal, interferometric and AI focus variation tophography and reflectometry
|
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| Performance | Depending on the objective chosen |
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| Substrates | Substrate size |
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| Substrate materials allowed |
| |
Optical Profiler (Filmetrics)
The Profilm3D optical profiler from Filmetrics uses white-light-interferometry (WLI) and phase-shifting-interferometry (PSI) to produce surface profiles and depth-of-field color images.
The main purpose is 3D topographic imaging of surfaces, step height measurements and roughness measurements with larger FOV (Field Of View) than the AFM, but less horisontal resolution.
For most samples the optical profiler provides fast and easy information without any sample preparation. However, it can be necessary to cover thin transparent layers (< 2 µm) with a thin layer of metal.
The resolution is limited by the objective and the sampling resolution.
The user manual, technical information and contact information can be found in LabManager:
Optical profiler (Filmetrics) info page in LabManager
| Equipment | Optical profiler | |
|---|---|---|
| Purpose | 3D topographic imaging of surfaces. |
|
| Posibilities | Interferometric profiling |
|
| Performance | With the current 10x objective | |
| Substrates | Substrate size |
|
| Substrate materials allowed |
| |
Dektak 3ST
The Dektak 3ST is intended for profile measurements on samples outside the cleanroom.
The user manual, technical information and contact information can be found in LabManager:
Dektak 3ST (Dektak) in LabManager
The computer connected to the Dektak 3ST is pretty old and runs Windows 98 SE. It is not connected to the network but traces can be saved on either USB memory stick or floppy disk. The USB driver is an old universal driver and has been shown to work with small size USB sticks. However it did not work with an 8GB Kingston stick.
| Performance | Vertical Range |
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|---|---|---|
| Scan length range |
| |
| Stylus track force |
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| Scan speed ranges |
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| Materials | Allowed substrate materials |
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Stylus Profiler: Dektak150
The stylus profiler Dektak150 is intended for profile measurements on samples outside the cleanroom.
The user manual, technical information and contact information can be found in LabManager:
Stylus profiler:Dektak150 in LabManager
The computer is not connected to the network but data can be saved on a dedicated USB and transfered to a computer on the network.
| Purpose | Profiler for measuring micro structures |
|
|---|---|---|
| Performance | Scan range x y |
Line scan x: 50 µm to 55 mm in a single scan |
| Scan range z |
50 Å to 1 mm | |
| Resolution x y |
Down to 0.003µm | |
| Resolution z |
1Å (@65kÅ), 10Å (@655 kÅ), 80 Å (@5240 kÅ), 160 Å (@1mm) | |
| Maximum sample thickness |
100mm | |
| Hardware settings | Tip radius |
|
| Substrates | Substrate size |
|
| Substrate materials allowed |
|