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1 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Laurens Pluimers Supervisors: Dr.ir.

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Presentation on theme: "1 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Laurens Pluimers Supervisors: Dr.ir."— Presentation transcript:

1 1 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Laurens Pluimers Supervisors: Dr.ir. W.M. van Spengen Prof.dr.ir. A. van Keulen

2 2 Challenge the future 10 3 10 0 10 -3 10 -6 10 -9 Micrometer(µm) Nanometer(nm) Picometer(pm) Millimeter(mm) Meter(m ) Kilometer(km ) Scaling 10 -12

3 3 Challenge the future Microscopes Hair: 40-80 µm DNA: 10-30 nm Atoms: 30-300 pm Optical microscope Resolution: 200nm Resolution: 100pm Source: andrew.cmu.edu Atomic force microscope (AFM)

4 4 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability

5 5 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability

6 6 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability

7 7 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Outline  Introduction Atomic Force Microscope (AFM)

8 8 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Outline  Introduction Atomic Force Microscope (AFM)  Probe calibration

9 9 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Outline  Introduction Atomic Force Microscope (AFM)  Probe calibration  Electrostatic pull-in instability

10 10 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Outline  Introduction Atomic Force Microscope (AFM)  Probe calibration  Electrostatic pull-in instability  Results of feasibility study

11 11 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Outline  Introduction Atomic Force Microscope (AFM)  Probe calibration  Electrostatic pull-in instability  Results of feasibility study  Conclusions & Recommendations

12 12 Challenge the future Atomic Force Microscope Working principle Quadrant detector Laser Cantilever beam(probe) Sample Source: www.bruker.com

13 13 Challenge the future Atomic Force Microscope Working principle Source: http://www.youtube.com/watch?v=fivhcWYEtkQ

14 14 Challenge the future Atomic Force Microscope Setup: Optical beam deflection system

15 15 Challenge the future Atomic Force Microscope AFM probe 20μm Source: www.absoluteastronomy.com

16 16 Challenge the future Atomic Force Microscope Images Topography image of metallic nanoparticles deposited on graphite Source: www.oist.jp

17 17 Challenge the future Recap What is an Atomic Force Microscope (AFM)?  “Feeling” the sample surface with probe  Optical beam deflection system  Resolution ~100pm √

18 18 Challenge the future Atomic Force Microscope Modes of operation  Imaging  Topography scan  Force measurements  Material properties

19 19 Challenge the future Atomic Force Microscope Mode of operation: Force measurements Measurement tip / sample interaction forces:  Atomic bonding  Van der Waals forces  Magnetic forces  Chemical bonding Probe Sample h Source: www.bruker.com

20 20 Challenge the future Atomic Force Microscope Interaction forces Material A Material B Quadrant detector Laser Probe F int

21 21 Challenge the future Atomic Force Microscope Interaction forces x y “Force” image Material A Material B

22 22 Challenge the future Atomic Force Microscope Probe calibration k F int x Hooke’s law F int =k ·x Probe Laser Quadrant detector k=spring constant

23 23 Challenge the future Probe calibration Added mass M x Hooke’s law k

24 24 Challenge the future Probe calibration Euler-Bernoulli beam theory t L b Cantilever base

25 25 Challenge the future Probe calibration Other calibration methods MethodAccuracyDisadvantages Added mass15-25%Destructive, slow Euler-Bernoulli beam theory 20-40%Inaccurate, slow Nano-Force Balance0.4%External equipment, expensive Thermal tune20%Only compliant beams

26 26 Challenge the future Recap Why do you need to calibrate the probe?  To determine the exact interaction forces between tip and sample  Bonding forces  Material properties Disadvantages other methods  Need for new method √

27 27 Challenge the future Probe calibration New calibration method Based on probe’s Electrostatic Pull-in Instability (EPI) Inventor: Prof.dr.ir. F. van Keulen Improvements:  Wide range of cantilever beams (k= 0.1 – 50 N/m)  Non-destructive  Integrated system in AFM  Fast and easy to use

28 28 Challenge the future Probe calibration New calibration method Based on probe’s Electrostatic Pull-in Instability (EPI)  EPI  Probe calibration using EPI  Experimental setup

29 29 Challenge the future Electrostatic Pull-in Instability V u=d 0 u Probe Counter electrode DC voltage source Pull-in point

30 30 Challenge the future Electrostatic Pull-in Instability Top view cantilever beam

31 31 Challenge the future  Non-linear behaviour of the cantilever beam  Elastic restoring forces are linear  Electrostatic forces are quadratic  Main advantage: well defined instability point(pull-in)  measurement Electrostatic Pull-in Instability

32 32 Challenge the future Probe calibration Electrostatic pull-in instability L b d0d0

33 33 Challenge the future Probe calibration EPI: differential gap method V p1 V V V p2 Δd Δd

34 34 Challenge the future EPI probe calibration Experimental setup Variables:  Differential gap ( Δd )  Pull-in voltage (V pi )  Length (L)  Width (b) Accuracy: 5 -15 % Model Source: www.bruker.com AFM system

35 35 Challenge the future EPI probe calibration Experimental setup XYZ stage Variables:  Differential gap ( Δd ) XYZ stage Source: www.bruker.com

36 36 Challenge the future EPI probe calibration Experimental setup Variables:  Differential gap ( Δd )  Pull-in voltage (V pi ) Source: www.bruker.com XYZ stage Counter electrode XYZ stage

37 37 Challenge the future EPI probe calibration Experimental setup Variables:  Differential gap ( Δd )  Pull-in voltage (V pi ) Source: www.bruker.com Counter electrode XYZ stage

38 38 Challenge the future EPI probe calibration Experimental setup Variables:  Differential gap ( Δd )  Pull-in voltage (V pi )  Length (L)  Width (b) Source: www.bruker.com Counter electrode XYZ stage Aspheric lens

39 39 Challenge the future EPI probe calibration Calibration mode Source: www.bruker.com Variable:  Pull-in voltage (V pi ) Source: www.bruker.com

40 40 Challenge the future EPI probe calibration Width scan x Source: www.bruker.com Variable:  Width (b) Source: www.bruker.com

41 41 Challenge the future EPI probe calibration Length scan y Source: www.bruker.com Variable:  Length (L) Source: www.bruker.com

42 42 Challenge the future EPI probe calibration Experimental setup Source: www.bruker.com

43 43 Challenge the future Probe calibration Experimental setup Optical path Laser Aspheric lens Quadrant detector

44 44 Challenge the future Probe calibration Experimental setup

45 45 Challenge the future Probe calibration Experimental setup

46 46 Challenge the future Probe calibration Experimental setup

47 47 Challenge the future Probe calibration Experimental setup

48 48 Challenge the future Probe calibration Experimental setup

49 49 Challenge the future Results Performance check:  Differential gap ( Δd )  Pull-in voltage (V pi )  Length (L)  Width (w) Calibration test probe

50 50 Challenge the future Results Width scan Width Position stage [µm] QD output [V] Width scan EPI

51 51 Challenge the future Results Length scan Length Position stage [µm] QD output [V] Length scan EPI

52 52 Challenge the future Results Length/Width scan Width [µm]Length[µm] EPI50.59 ±0.15 467.34 ±0.40 Bruker WL50.71 ±0.3 466.02 ±0.3 Error [µm] 0.12 ±0.33 1.32 ±0.5 Error [%] 0.230.28

53 53 Challenge the future Results Calibration test probe ProbeSpring constant k [N/m]Δk [%] NanoWorldEPI 1 (compliant)0.17 2 (stiff)46 0.143 16.2 15.38 66.6 Requirement: Accuracy 5 -15 %

54 54 Challenge the future Conclusions Performance check:  EPI method can be implemented as integrated system Calibration test probe:  EPI calibration method is able to determine the spring constant of AFM probes  Accuracy system not within requirements

55 55 Challenge the future Recomendations Increase accuracy by improving model  Include fringing field effects  Tapered end beam My model Reality

56 56 Challenge the future Recommendations Increase accuracy by improving model  Include fringing field effects  Tapered end

57 57 Challenge the future Recommendations Increase accuracy by improving model  Include fringing field effects  Tapered end Cantilever beam

58 58 Challenge the future Recommendations Increase accuracy by improving model  Include fringing field effects  Tapered end New model in progress

59 59 Challenge the future Feasibility study for AFM probe calibration using the probe’s electrostatic pull-in instability Questions?

60 60 Challenge the future Extra sheet Width scan Width Position stage [µm] QD output [V] Width scan EPI

61 61 Challenge the future Extra sheet Width scan

62 62 Challenge the future Laser + Lens Quadrant detector Laser beam Width cantilever beam Extra sheet Width scan

63 63 Challenge the future Extra sheet Extended model

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