Specific Process Knowledge/Characterization/AFM: Atomic Force Microscopy

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AFM Icon 1 & 2

This section is written by Berit Herstrøm @DTU Nanolab

AFM Icon-Pt Positioned in clean room: C-1, photo: DTU Nanolab internal
AFM Icon-Pt 2 Positioned in the basement of building 346-904, photo: DTU Nanolab internal

DTU Nanolab has two pieces of Bruker AFM Dimension Icon-Pt. AFM stands for Atomic Force Microscope which is a scanning probe microscope where a sharp probe is scanned across a surface either in contact mode, tapping mode or PeakForce tapping mode. The outcome is a topographic plot of the surface. It has a lateral solution of about 1 nm and a vertical resolution of less than 1 Å which makes it very suitable for topographic characterization in the nanometer regime. The limiting factor however is often the size of the probe in use. The tip radius of curvature (ROC) can be from 2 nm up to more than 20 nm depending on the chosen probe. The half cone angle of the tip can vary from less than 3o to over 25o giving problems resolving high aspect ratio structures.

The main purposes are surface roughness measurements and step/structure high measurements in the nanometer and sub-micrometer regime. For larger structure see the topografic measurement page.

To get some product information from the vendor take a look at Bruker's homepage [1]


Before training: Please watch the training videos before the training on the instrument:

AFM Icon Part 1, AFM Icon Part 2 and AFM Icon Part 3

You can find them here: link to training videos

It is also recommanded to read Brukers presentation of contract mode, tapping mode and peak force tappping mode click HERE


The user manual, quality control procedure and results and contact information can be found in LabManager:
AFM Icon 1 in LabManager
AFM Icon 2 in LabManager

Process Information

Analysis software

  • Free analysis software: For visualizing and analyzing AFM and Optical profiler files (Nanoman and Sensofar) Gwyddion
  • or you can install Brukers own software analyses program that can be found on the cleanroom drive: U:\Nlab\CleanroomDrive\_Equipment\AFM\NanoScope_Analysis_x86_v170r1sr2.exe
  • or you can get a SPIP license for free if you are connected to one of the following institutes (Nanolab, Physics, Chemistry, Mechanics, Energikonvertering, this list may not be updated!) , by contacting Christian Michael Skram

An overview of the performance of the AFM Icon

Equipment AFM Icon AFM Icon 2
Position

Inside the cleanroom

In the basement of building 346 room 904

Purpose Topografic measurement in the nanometer and and sub-micrometer regime and electrical and mechanical measurements
  • Surface roughness measurement
  • Step/structure hight measurement
  • Surface image
  • Surface potential
  • Modulus
  • Adhesion
  • Deformation
  • Surface roughness measurement
  • Step/structure hight measurement
  • Surface image
Performance Scan range xy Up to 90 µm square Up to 90 µm square
Scan range z Up to 13µm Up to 13µm
Vertical noise floor <30pm RMS <30pm RMS
X-Y position noise (closed loop) <0.15nm RMS <0.15nm RMS
Z sensor noise level(closed loop) 35pm RMS 35pm RMS
Integral nonlinearity(X-Y-Z) <0.5% <0.5%
X-Y position noise (closed loop) <0.15nm RMS <0.15nm RMS
Height (z) accuracy better than 2% (at 200 nm), typically better then 0.75% better than 2% (at 200 nm), typically better then 0.75%
Max. scan depth as a function of trench width W ~1 for our standard probe. Can be improved to about 10 with the right probe ~1 for our standard probe. Can be improved to about 10 with the right probe
Hardware settings Tip radius of curvature Standard probe: <12 nm Standard probe: <12 nm
Standard soft tapping mode Cantilever/tip (can be used in both tapping mode and ScanAsyst mode) Tap150Al-G Tap150Al-G
Standard ScanAsyst mode Cantilever/tip ScanAsyst in Air ScanAsyst in Air
Standard Tapping mode Cantilevers/tips Tap300Al-G Tap300Al-G
Super Sharp Si Cantilever/tip SSS-NCHR SSS-NCHR
High Aspect Ratio Cantilever/tip AR5-NCHR AR5-NCHR
Cantilevers/tips vendor
Substrates Substrate size Up to 210mm in diameter and up to 15mm thick" Up to 210mm in diameter and up to 15mm thick"
Motorized stage (X-Y axis)
  • 180mmx150mm inspection area
  • 2µm repeatability, unidirectional
  • 3µm repeatability, bidirectional
  • 180mmx150mm inspection area
  • 2µm repeatability, unidirectional
  • 3µm repeatability, bidirectional
Substrate material allowed In principle all solid and none-poisonous materials In principle all solid and none-poisonous materials


Height Accuracy

Heigh accuracy estimations in AFM measurements are complex and depends on the scale you are interested in. At sub nanometer scale or a few nanometers the height measurement may be affected by the properties of the cantilever tip, your sample material stiffness and the scanning force. These parameters are less important when measuring in the 100 nm range and above. At all scales calibration of the Z-piezo is important.

Here at DTU Nanolab we calibrate the Z-piezo with a certified sample that is approximately 200 nm in height. This sample height is given with an uncertainty that is calculated based on variation on the calibration sample and measurement uncertainties of the instrument used for certification. The uncertainty on the calibration sample is ≤ 1.5 nm. Following our QC procedure we accept an offset from the certified value of 2%. For a 200 nm sample this is 4 nm. If we use the formula for combined uncertainties then the uncertainty is: 4.3 nm or 2.1% However when we check the value it is typically less then 1% off given a combined uncertainty of: 0.75%