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Kelvin probe force microscope

October 27, 2023

Kelvin probe force microscopy (KPFM), also known as surface potential microscopy, is a noncontact variant of atomic force microscopy (AFM).[1][2][3] By raster scanning in the x,y plane the work function of the sample can be locally mapped for correlation with sample features. When there is little or no magnification, this approach can be described as using a scanning Kelvin probe (SKP). These techniques are predominantly used to measure corrosion and coatings.

In Kelvin probe force microscopy, a conducting cantilever is scanned over a surface at a constant height in order to map the work function of the surface.
A typical scanning Kelvin probe (SKP) instrument. On the left is the control unit with lock-in amplifier and backing potential controller. On the right is the x, y, z scanning axis with vibrator, electrometer and probe mounted.

With KPFM, the work function of surfaces can be observed at atomic or molecular scales. The work function relates to many surface phenomena, including catalytic activity, reconstruction of surfaces, doping and band-bending of semiconductors, charge trapping in dielectrics and corrosion. The map of the work function produced by KPFM gives information about the composition and electronic state of the local structures on the surface of a solid.

History edit

The SKP technique is based on parallel plate capacitor experiments performed by Lord Kelvin in 1898.[4] In the 1930s William Zisman built upon Lord Kelvin's experiments to develop a technique to measure contact potential differences of dissimilar metals.[5]

Working principle edit

 
The changes to the Fermi levels of the scanning Kelvin probe (SKP) sample and probe during measurement are shown. On the electrical connection of the probe and sample their Fermi levels equilibrate, and a charge develops at the probe and sample. A backing potential is applied to null this charge, returning the sample Fermi level to its original position.

In SKP the probe and sample are held parallel to each other and electrically connected to form a parallel plate capacitor. The probe is selected to be of a different material to the sample, therefore each component initially has a distinct Fermi level. When electrical connection is made between the probe and the sample electron flow can occur between the probe and the sample in the direction of the higher to the lower Fermi level. This electron flow causes the equilibration of the probe and sample Fermi levels. Furthermore, a surface charge develops on the probe and the sample, with a related potential difference known as the contact potential (Vc). In SKP the probe is vibrated along a perpendicular to the plane of the sample.[6] This vibration causes a change in probe to sample distance, which in turn results in the flow of current, taking the form of an ac sine wave. The resulting ac sine wave is demodulated to a dc signal through the use of a lock-in amplifier.[7] Typically the user must select the correct reference phase value used by the lock-in amplifier. Once the dc potential has been determined, an external potential, known as the backing potential (Vb) can be applied to null the charge between the probe and the sample. When the charge is nullified, the Fermi level of the sample returns to its original position. This means that Vb is equal to -Vc, which is the work function difference between the SKP probe and the sample measured.[8]

 
Simplified illustration of the scanning Kelvin probe (SKP) technique. The probe is shown to vibrate in z, perpendicular to the sample plane. The probe and sample form a parallel plate capacitor as shown.
 
Block diagram of a scanning Kelvin probe (SKP) instrument showing computer, control unit, scan axes, vibrator, probe, and sample

The cantilever in the AFM is a reference electrode that forms a capacitor with the surface, over which it is scanned laterally at a constant separation. The cantilever is not piezoelectrically driven at its mechanical resonance frequency ω0 as in normal AFM although an alternating current (AC) voltage is applied at this frequency.

When there is a direct-current (DC) potential difference between the tip and the surface, the AC+DC voltage offset will cause the cantilever to vibrate. The origin of the force can be understood by considering that the energy of the capacitor formed by the cantilever and the surface is

 

plus terms at DC. Only the cross-term proportional to the VDC·VAC product is at the resonance frequency ω0. The resulting vibration of the cantilever is detected using usual scanned-probe microscopy methods (typically involving a diode laser and a four-quadrant detector). A null circuit is used to drive the DC potential of the tip to a value which minimizes the vibration. A map of this nulling DC potential versus the lateral position coordinate therefore produces an image of the work function of the surface.

A related technique, electrostatic force microscopy (EFM), directly measures the force produced on a charged tip by the electric field emanating from the surface. EFM operates much like magnetic force microscopy in that the frequency shift or amplitude change of the cantilever oscillation is used to detect the electric field. However, EFM is much more sensitive to topographic artifacts than KPFM. Both EFM and KPFM require the use of conductive cantilevers, typically metal-coated silicon or silicon nitride. Another AFM-based technique for the imaging of electrostatic surface potentials, scanning quantum dot microscopy,[9] quantifies surface potentials based on their ability to gate a tip-attached quantum dot.

Factors affecting SKP measurements edit

The quality of an SKP measurement is affected by a number of factors. This includes the diameter of the SKP probe, the probe to sample distance, and the material of the SKP probe. The probe diameter is important in the SKP measurement because it affects the overall resolution of the measurement, with smaller probes leading to improved resolution.[10][11] On the other hand, reducing the size of the probe causes an increase in fringing effects which reduces the sensitivity of the measurement by increasing the measurement of stray capacitances.[10] The material used in the construction of the SKP probe is important to the quality of the SKP measurement.[12] This occurs for a number of reasons. Different materials have different work function values which will affect the contact potential measured. Different materials have different sensitivity to humidity changes. The material can also affect the resulting lateral resolution of the SKP measurement. In commercial probes tungsten is used,[13] though probes of platinum,[14] copper,[15] gold,[16] and NiCr has been used.[17] The probe to sample distance affects the final SKP measurement, with smaller probe to sample distances improving the lateral resolution [11] and the signal-to-noise ratio of the measurement.[18] Furthermore, reducing the SKP probe to sample distance increases the intensity of the measurement, where the intensity of the measurement is proportional to 1/d2, where d is the probe to sample distance.[19] The effects of changing probe to sample distance on the measurement can be counteracted by using SKP in constant distance mode.

Work function edit

The Kelvin probe force microscope or Kelvin force microscope (KFM) is based on an AFM set-up and the determination of the work function is based on the measurement of the electrostatic forces between the small AFM tip and the sample. The conducting tip and the sample are characterized by (in general) different work functions, which represent the difference between the Fermi level and the vacuum level for each material. If both elements were brought in contact, a net electric current would flow between them until the Fermi levels were aligned. The difference between the work functions is called the contact potential difference and is denoted generally with VCPD. An electrostatic force exists between tip and sample, because of the electric field between them. For the measurement a voltage is applied between tip and sample, consisting of a DC-bias VDC and an AC-voltage VAC sin(ωt) of frequency ω.

 

Tuning the AC-frequency to the resonant frequency of the AFM cantilever results in an improved sensitivity. The electrostatic force in a capacitor may be found by differentiating the energy function with respect to the separation of the elements and can be written as

 

where C is the capacitance, z is the separation, and V is the voltage, each between tip and surface. Substituting the previous formula for voltage (V) shows that the electrostatic force can be split up into three contributions, as the total electrostatic force F acting on the tip then has spectral components at the frequencies ω and .

 

The DC component, FDC, contributes to the topographical signal, the term Fω at the characteristic frequency ω is used to measure the contact potential and the contribution F can be used for capacitance microscopy.

 
 
 

Contact potential measurements edit

For contact potential measurements a lock-in amplifier is used to detect the cantilever oscillation at ω. During the scan VDC will be adjusted so that the electrostatic forces between the tip and the sample become zero and thus the response at the frequency ω becomes zero. Since the electrostatic force at ω depends on VDC − VCPD, the value of VDC that minimizes the ω-term corresponds to the contact potential. Absolute values of the sample work function can be obtained if the tip is first calibrated against a reference sample of known work function.[20] Apart from this, one can use the normal topographic scan methods at the resonance frequency ω independently of the above. Thus, in one scan, the topography and the contact potential of the sample are determined simultaneously. This can be done in (at least) two different ways: 1) The topography is captured in AC mode which means that the cantilever is driven by a piezo at its resonant frequency. Simultaneously the AC voltage for the KPFM measurement is applied at a frequency slightly lower than the resonant frequency of the cantilever. In this measurement mode the topography and the contact potential difference are captured at the same time and this mode is often called single-pass. 2) One line of the topography is captured either in contact or AC mode and is stored internally. Then, this line is scanned again, while the cantilever remains on a defined distance to the sample without a mechanically driven oscillation but the AC voltage of the KPFM measurement is applied and the contact potential is captured as explained above. It is important to note that the cantilever tip must not be too close to the sample in order to allow good oscillation with applied AC voltage. Therefore, KPFM can be performed simultaneously during AC topography measurements but not during contact topography measurements.

Applications edit

The Volta potential measured by SKP is directly proportional to the corrosion potential of a material,[21] as such SKP has found widespread use in the study of the fields of corrosion and coatings. In the field of coatings for example, a scratched region of a self-healing shape memory polymer coating containing a heat generating agent on aluminium alloys was measured by SKP.[22] Initially after the scratch was made the Volta potential was noticeably higher and wider over the scratch than over the rest of the sample, implying this region is more likely to corrode. The Volta potential decreased over subsequent measurements, and eventually the peak over the scratch completely disappeared implying the coating has healed. Because SKP can be used to investigate coatings in a non-destructive way it has also been used to determine coating failure. In a study of polyurethane coatings, it was seen that the work function increases with increasing exposure to high temperature and humidity.[23] This increase in work function is related to decomposition of the coating likely from hydrolysis of bonds within the coating.

Using SKP the corrosion of industrially important alloys has been measured.[citation needed] In particular with SKP it is possible to investigate the effects of environmental stimulus on corrosion. For example, the microbially induced corrosion of stainless steel and titanium has been examined.[24] SKP is useful to study this sort of corrosion because it usually occurs locally, therefore global techniques are poorly suited. Surface potential changes related to increased localized corrosion were shown by SKP measurements. Furthermore, it was possible to compare the resulting corrosion from different microbial species. In another example SKP was used to investigate biomedical alloy materials, which can be corroded within the human body. In studies on Ti-15Mo under inflammatory conditions,[25] SKP measurements showed a lower corrosion resistance at the bottom of a corrosion pit than at the oxide protected surface of the alloy. SKP has also been used to investigate the effects of atmospheric corrosion, for example to investigate copper alloys in marine environment.[26] In this study Kelvin potentials became more positive, indicating a more positive corrosion potential, with increased exposure time, due to an increase in thickness of corrosion products. As a final example SKP was used to investigate stainless steel under simulated conditions of gas pipeline.[27] These measurements showed an increase in difference in corrosion potential of cathodic and anodic regions with increased corrosion time, indicating a higher likelihood of corrosion. Furthermore, these SKP measurements provided information about local corrosion, not possible with other techniques.

SKP has been used to investigate the surface potential of materials used in solar cells, with the advantage that it is a non-contact, and therefore a non-destructive technique.[28] It can be used to determine the electron affinity of different materials in turn allowing the energy level overlap of conduction bands of differing materials to be determined. The energy level overlap of these bands is related to the surface photovoltage response of a system.[29]

As a non-contact, non-destructive technique SKP has been used to investigate latent fingerprints on materials of interest for forensic studies.[30] When fingerprints are left on a metallic surface they leave behind salts which can cause the localized corrosion of the material of interest. This leads to a change in Volta potential of the sample, which is detectable by SKP. SKP is particularly useful for these analyses because it can detect this change in Volta potential even after heating, or coating by, for example, oils.

SKP has been used to analyze the corrosion mechanisms of schreibersite-containing meteorites.[31][32] The aim of these studies has been to investigate the role in such meteorites in releasing species utilized in prebiotic chemistry.

In the field of biology SKP has been used to investigate the electric fields associated with wounding,[33] and acupuncture points.[34]

In the field of electronics, KPFM is used to investigate the charge trapping in High-k gate oxides/interfaces of electronic devices.[35][36][37]

See also edit

References edit

  1. ^ M. Nonnenmacher; M. P. O'Boyle; H. K. Wickramasinghe (1991). (PDF). Appl. Phys. Lett. 58 (25): 2921. Bibcode:1991ApPhL..58.2921N. doi:10.1063/1.105227. Archived from the original (free-download pdf) on 2009-09-20.
  2. ^ Fujihira, Masamichi (1999). "Kelvin Probe Force Microscopy of Molecular Surfaces". Annual Review of Materials Science. 29 (1): 353–380. Bibcode:1999AnRMS..29..353F. doi:10.1146/annurev.matsci.29.1.353. ISSN 0084-6600.
  3. ^ Melitz, Wilhelm; Shen, Jian; Kummel, Andrew C.; Lee, Sangyeob (2011). "Kelvin probe force microscopy and its application". Surface Science Reports. 66 (1): 1–27. Bibcode:2011SurSR..66....1M. doi:10.1016/j.surfrep.2010.10.001. ISSN 0167-5729.
  4. ^ Kelvin, Lord (1898). "V. Contact electricity of metals". The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science. 46 (278): 82–120. doi:10.1080/14786449808621172. ISSN 1941-5982.
  5. ^ Zisman, W. A. (1932). "A New Method of Measuring Contact Potential Differences in Metals". Review of Scientific Instruments. 3 (7): 367–370. Bibcode:1932RScI....3..367Z. doi:10.1063/1.1748947. ISSN 0034-6748.
  6. ^ Rohwerder, Michael; Turcu, Florin (2007). "High-resolution Kelvin probe microscopy in corrosion science: Scanning Kelvin probe force microscopy (SKPFM) versus classical scanning Kelvin probe (SKP)". Electrochimica Acta. 53 (2): 290–299. doi:10.1016/j.electacta.2007.03.016.
  7. ^ Cheran, Larisa-Emilia; Johnstone, Sherri; Sadeghi, Saman; Thompson, Michael (2007-01-19). "Work-function measurement by high-resolution scanning Kelvin nanoprobe". Measurement Science and Technology. 18 (3): 567–578. Bibcode:2007MeScT..18..567C. doi:10.1088/0957-0233/18/3/005. ISSN 0957-0233. S2CID 123457387.
  8. ^ Surplice, N A; D'Arcy, R J (1970). "A critique of the Kelvin method of measuring work functions". Journal of Physics E: Scientific Instruments. 3 (7): 477–482. doi:10.1088/0022-3735/3/7/201. ISSN 0022-3735.
  9. ^ Wagner, Christian; Green, Matthew F. B.; Leinen, Philipp; Deilmann, Thorsten; Krüger, Peter; Rohlfing, Michael; Temirov, Ruslan; Tautz, F. Stefan (2015-07-06). "Scanning Quantum Dot Microscopy". Physical Review Letters. 115 (2): 026101. arXiv:1503.07738. Bibcode:2015PhRvL.115b6101W. doi:10.1103/PhysRevLett.115.026101. ISSN 0031-9007. PMID 26207484. S2CID 1720328.
  10. ^ a b Wicinski, Mariusz; Burgstaller, Wolfgang; Hassel, Achim Walter (2016). "Lateral resolution in scanning Kelvin probe microscopy". Corrosion Science. 104: 1–8. doi:10.1016/j.corsci.2015.09.008.
  11. ^ a b McMurray, H. N.; Williams, G. (2002). "Probe diameter and probe–specimen distance dependence in the lateral resolution of a scanning Kelvin probe". Journal of Applied Physics. 91 (3): 1673–1679. Bibcode:2002JAP....91.1673M. doi:10.1063/1.1430546. ISSN 0021-8979.
  12. ^ Huber, Silvia; Wicinski, Mariusz; Hassel, Achim Walter (2018). "Suitability of Various Materials for Probes in Scanning Kelvin Probe Measurements". Physica Status Solidi A. 215 (15): 1700952. Bibcode:2018PSSAR.21500952H. doi:10.1002/pssa.201700952.
  13. ^ "High Resolution Scanning Kelvin Probe". Bio-Logic Science Instruments. Retrieved 2019-05-17.
  14. ^ Hansen, Douglas C.; Hansen, Karolyn M.; Ferrell, Thomas L.; Thundat, Thomas (2003). "Discerning Biomolecular Interactions Using Kelvin Probe Technology". Langmuir. 19 (18): 7514–7520. doi:10.1021/la034333w. ISSN 0743-7463.
  15. ^ Dirscherl, Konrad; Baikie, Iain; Forsyth, Gregor; Heide, Arvid van der (2003). "Utilisation of a micro-tip scanning Kelvin probe for non-invasive surface potential mapping of mc-Si solar cells". Solar Energy Materials and Solar Cells. 79 (4): 485–494. doi:10.1016/S0927-0248(03)00064-3.
  16. ^ Stratmann, M. (1987). "The investigation of the corrosion properties of metals, covered with adsorbed electrolyte layers—A new experimental technique". Corrosion Science. 27 (8): 869–872. doi:10.1016/0010-938X(87)90043-6.
  17. ^ Nazarov, A. P.; Thierry, D. (2001). "Study of the Carbon Steel/Alkyd Coating Interface with a Scanning Vibrating Capacitor Technique". Protection of Metals. 37 (2): 108–119. doi:10.1023/a:1010361702449. ISSN 0033-1732. S2CID 92117439.
  18. ^ "Height tracking with the SKP370 or SKP470 module" (PDF). Bio-Logic Science Instruments. Retrieved 2019-05-17.
  19. ^ Wapner, K.; Schoenberger, B.; Stratmann, M.; Grundmeier, G. (2005). "Height-Regulating Scanning Kelvin Probe for Simultaneous Measurement of Surface Topology and Electrode Potentials at Buried Polymer/Metal Interfaces". Journal of the Electrochemical Society. 152 (3): E114. Bibcode:2005JElS..152E.114W. doi:10.1149/1.1856914.
  20. ^ Fernández Garrillo, P. A.; Grévin, B.; Chevalier, N.; Borowik, Ł. (2018). "Calibrated work function mapping by Kelvin probe force microscopy" (PDF). Review of Scientific Instruments. 89 (4): 043702. Bibcode:2018RScI...89d3702F. doi:10.1063/1.5007619. PMID 29716375.
  21. ^ "SKP imaging example of a corroded Zn-plated Fe sample" (PDF). Bio-Logic Science Instruments. Retrieved 2019-05-17.
  22. ^ Fan, Weijie; Zhang, Yong; Li, Weihua; Wang, Wei; Zhao, Xiaodong; Song, Liying (2019). "Multi-level self-healing ability of shape memory polyurethane coating with microcapsules by induction heating". Chemical Engineering Journal. 368: 1033–1044. doi:10.1016/j.cej.2019.03.027. S2CID 104432686.
  23. ^ Borth, David J.; Iezzi, Erick B.; Dudis, Douglas S.; Hansen, Douglas C. (2019). "Nondestructive Evaluation of Urethane-Ester Coating Systems Using the Scanning Kelvin Probe Technique". Corrosion. 75 (5): 457–464. doi:10.5006/3020. ISSN 0010-9312. S2CID 105314795.
  24. ^ Zhang, Dawei; Zhou, Feichi; Xiao, Kui; Cui, Tianyu; Qian, Hongchong; Li, Xiaogang (2015). "Microbially Influenced Corrosion of 304 Stainless Steel and Titanium by P. variotii and A. niger in Humid Atmosphere". Journal of Materials Engineering and Performance. 24 (7): 2688–2698. Bibcode:2015JMEP...24.2688Z. doi:10.1007/s11665-015-1558-2. ISSN 1059-9495. S2CID 137116966.
  25. ^ Szklarska, M.; Dercz, G.; Kubisztal, J.; Balin, K.; Łosiewicz, B. (2016). "Semi-Conducting Properties of Titanium Dioxide Layer on Surface of Ti-15Mo Implant Alloy in Biological Milieu". Acta Physica Polonica A. 130 (4): 1085–1087. Bibcode:2016AcPPA.130.1085S. doi:10.12693/APhysPolA.130.1085. ISSN 0587-4246.
  26. ^ Kong, Decheng; Dong, Chaofang; Ni, Xiaoqing; Man, Cheng; Xiao, Kui; Li, Xiaogang (2018). "Insight into the mechanism of alloying elements (Sn, Be) effect on copper corrosion during long-term degradation in harsh marine environment". Applied Surface Science. 455: 543–553. Bibcode:2018ApSS..455..543K. doi:10.1016/j.apsusc.2018.06.029. S2CID 102769318.
  27. ^ Jin, Z.H.; Ge, H.H.; Lin, W.W.; Zong, Y.W.; Liu, S.J.; Shi, J.M. (2014). "Corrosion behaviour of 316L stainless steel and anti-corrosion materials in a high acidified chloride solution". Applied Surface Science. 322: 47–56. Bibcode:2014ApSS..322...47J. doi:10.1016/j.apsusc.2014.09.205.
  28. ^ Dirscherl, Konrad; Baikie, Iain; Forsyth, Gregor; Heide, Arvid van der (2003). "Utilisation of a micro-tip scanning Kelvin probe for non-invasive surface potential mapping of mc-Si solar cells". Solar Energy Materials and Solar Cells. 79 (4): 485–494. doi:10.1016/s0927-0248(03)00064-3. ISSN 0927-0248.
  29. ^ Liu, Xiangyang; Zheng, Haiwu; Zhang, Jiwei; Xiao, Yin; Wang, Zhiyong (2013). "Photoelectric properties and charge dynamics for a set of solid state solar cells with Cu4Bi4S9 as the absorber layer". Journal of Materials Chemistry A. 1 (36): 10703. doi:10.1039/c3ta11830d. ISSN 2050-7488.
  30. ^ Williams, Geraint; McMurray, H. N. (2008). "Human Fingerprint - Metal Interactions Studied Using a Scanning Kelvin Probe". ECS Transactions. Washington, DC: ECS. 11 (22): 81–89. Bibcode:2008ECSTr..11v..81W. doi:10.1149/1.2925265. S2CID 98393112.
  31. ^ Bryant, David E.; Greenfield, David; Walshaw, Richard D.; Evans, Suzanne M.; Nimmo, Alexander E.; Smith, Caroline L.; Wang, Liming; Pasek, Matthew A.; Kee, Terence P. (2009). "Electrochemical studies of iron meteorites: phosphorus redox chemistry on the early Earth". International Journal of Astrobiology. 8 (1): 27–36. Bibcode:2009IJAsB...8...27B. doi:10.1017/S1473550408004345. ISSN 1473-5504. S2CID 97821022.
  32. ^ Bryant, David E.; Greenfield, David; Walshaw, Richard D.; Johnson, Benjamin R.G.; Herschy, Barry; Smith, Caroline; Pasek, Matthew A.; Telford, Richard; Scowen, Ian (2013). "Hydrothermal modification of the Sikhote-Alin iron meteorite under low pH geothermal environments. A plausibly prebiotic route to activated phosphorus on the early Earth". Geochimica et Cosmochimica Acta. 109: 90–112. Bibcode:2013GeCoA.109...90B. doi:10.1016/j.gca.2012.12.043.
  33. ^ Nuccitelli, Richard; Nuccitelli, Pamela; Ramlatchan, Samdeo; Sanger, Richard; Smith, Peter J.S. (2008). "Imaging the electric field associated with mouse and human skin wounds". Wound Repair and Regeneration. 16 (3): 432–441. doi:10.1111/j.1524-475X.2008.00389.x. ISSN 1067-1927. PMC 3086402. PMID 18471262.
  34. ^ Gow, Brian J.; Cheng, Justine L.; Baikie, Iain D.; Martinsen, Ørjan G.; Zhao, Min; Smith, Stephanie; Ahn, Andrew C. (2012). "Electrical Potential of Acupuncture Points: Use of a Noncontact Scanning Kelvin Probe". Evidence-Based Complementary and Alternative Medicine. 2012: 632838. doi:10.1155/2012/632838. ISSN 1741-427X. PMC 3541002. PMID 23320033.
  35. ^ Tzeng, S.-D.; Gwo, S. (2006-07-15). "Charge trapping properties at silicon nitride/silicon oxide interface studied by variable-temperature electrostatic force microscopy". Journal of Applied Physics. 100 (2): 023711–023711–9. Bibcode:2006JAP...100b3711T. doi:10.1063/1.2218025. ISSN 0021-8979.
  36. ^ Khosla, Robin; Kumar, Pawan; Sharma, Satinder K. (December 2015). "Charge Trapping and Decay Mechanism in Post Deposition Annealed Er2O3 MOS Capacitors by Nanoscopic and Macroscopic Characterization". IEEE Transactions on Device and Materials Reliability. 15 (4): 610–616. doi:10.1109/TDMR.2015.2498310. ISSN 1530-4388. S2CID 33548746.
  37. ^ Khosla, Robin; Rolseth, Erlend Granbo; Kumar, Pawan; Vadakupudhupalayam, Senthil Srinivasan; Sharma, Satinder K.; Schulze, Jorg (March 2017). "Charge Trapping Analysis of Metal/Al 2 O 3 /SiO 2 /Si, Gate Stack for Emerging Embedded Memories". IEEE Transactions on Device and Materials Reliability. 17 (1): 80–89. doi:10.1109/TDMR.2017.2659760. ISSN 1530-4388. S2CID 24247825.

External links edit

  • Masaki Takihara (9 December 2008). . Takahashi Lab., Institute of Industrial Science, University of Tokyo. Archived from the original on 29 October 2012. Retrieved 29 February 2012. – Full description of the principles with good illustrations to aid comprehension
  • Transport measurements by Scanning Probe Microscopy
  • Introduction to Kelvin Probe Force Microscopy (KPFM)
  • Dynamic Kelvin Probe Force Microscopy
  • Kelvin Probe Force Microscopy of Lateral Devices
  • Kelvin Probe Force Microscopy in Liquids
  • Current-voltage Measurements in Scanning Probe Microscopy
  • Dynamic IV measurements in SPM

October 27, 2023
kelvin, probe, force, microscope, kelvin, probe, force, microscopy, kpfm, also, known, surface, potential, microscopy, noncontact, variant, atomic, force, microscopy, raster, scanning, plane, work, function, sample, locally, mapped, correlation, with, sample, . Kelvin probe force microscopy KPFM also known as surface potential microscopy is a noncontact variant of atomic force microscopy AFM 1 2 3 By raster scanning in the x y plane the work function of the sample can be locally mapped for correlation with sample features When there is little or no magnification this approach can be described as using a scanning Kelvin probe SKP These techniques are predominantly used to measure corrosion and coatings In Kelvin probe force microscopy a conducting cantilever is scanned over a surface at a constant height in order to map the work function of the surface A typical scanning Kelvin probe SKP instrument On the left is the control unit with lock in amplifier and backing potential controller On the right is the x y z scanning axis with vibrator electrometer and probe mounted With KPFM the work function of surfaces can be observed at atomic or molecular scales The work function relates to many surface phenomena including catalytic activity reconstruction of surfaces doping and band bending of semiconductors charge trapping in dielectrics and corrosion The map of the work function produced by KPFM gives information about the composition and electronic state of the local structures on the surface of a solid Contents 1 History 2 Working principle 3 Factors affecting SKP measurements 4 Work function 5 Contact potential measurements 6 Applications 7 See also 8 References 9 External linksHistory editThe SKP technique is based on parallel plate capacitor experiments performed by Lord Kelvin in 1898 4 In the 1930s William Zisman built upon Lord Kelvin s experiments to develop a technique to measure contact potential differences of dissimilar metals 5 Working principle edit nbsp The changes to the Fermi levels of the scanning Kelvin probe SKP sample and probe during measurement are shown On the electrical connection of the probe and sample their Fermi levels equilibrate and a charge develops at the probe and sample A backing potential is applied to null this charge returning the sample Fermi level to its original position In SKP the probe and sample are held parallel to each other and electrically connected to form a parallel plate capacitor The probe is selected to be of a different material to the sample therefore each component initially has a distinct Fermi level When electrical connection is made between the probe and the sample electron flow can occur between the probe and the sample in the direction of the higher to the lower Fermi level This electron flow causes the equilibration of the probe and sample Fermi levels Furthermore a surface charge develops on the probe and the sample with a related potential difference known as the contact potential Vc In SKP the probe is vibrated along a perpendicular to the plane of the sample 6 This vibration causes a change in probe to sample distance which in turn results in the flow of current taking the form of an ac sine wave The resulting ac sine wave is demodulated to a dc signal through the use of a lock in amplifier 7 Typically the user must select the correct reference phase value used by the lock in amplifier Once the dc potential has been determined an external potential known as the backing potential Vb can be applied to null the charge between the probe and the sample When the charge is nullified the Fermi level of the sample returns to its original position This means that Vb is equal to Vc which is the work function difference between the SKP probe and the sample measured 8 nbsp Simplified illustration of the scanning Kelvin probe SKP technique The probe is shown to vibrate in z perpendicular to the sample plane The probe and sample form a parallel plate capacitor as shown nbsp Block diagram of a scanning Kelvin probe SKP instrument showing computer control unit scan axes vibrator probe and sampleThe cantilever in the AFM is a reference electrode that forms a capacitor with the surface over which it is scanned laterally at a constant separation The cantilever is not piezoelectrically driven at its mechanical resonance frequency w0 as in normal AFM although an alternating current AC voltage is applied at this frequency When there is a direct current DC potential difference between the tip and the surface the AC DC voltage offset will cause the cantilever to vibrate The origin of the force can be understood by considering that the energy of the capacitor formed by the cantilever and the surface is E 1 2 C V D C V A C sin w 0 t 2 1 2 C 2 V D C V A C sin w 0 t 1 2 V A C 2 cos 2 w 0 t displaystyle E frac 1 2 C V DC V AC sin omega 0 t 2 frac 1 2 C 2V DC V AC sin omega 0 t frac 1 2 V AC 2 cos 2 omega 0 t nbsp plus terms at DC Only the cross term proportional to the VDC VAC product is at the resonance frequency w0 The resulting vibration of the cantilever is detected using usual scanned probe microscopy methods typically involving a diode laser and a four quadrant detector A null circuit is used to drive the DC potential of the tip to a value which minimizes the vibration A map of this nulling DC potential versus the lateral position coordinate therefore produces an image of the work function of the surface A related technique electrostatic force microscopy EFM directly measures the force produced on a charged tip by the electric field emanating from the surface EFM operates much like magnetic force microscopy in that the frequency shift or amplitude change of the cantilever oscillation is used to detect the electric field However EFM is much more sensitive to topographic artifacts than KPFM Both EFM and KPFM require the use of conductive cantilevers typically metal coated silicon or silicon nitride Another AFM based technique for the imaging of electrostatic surface potentials scanning quantum dot microscopy 9 quantifies surface potentials based on their ability to gate a tip attached quantum dot Factors affecting SKP measurements editThe quality of an SKP measurement is affected by a number of factors This includes the diameter of the SKP probe the probe to sample distance and the material of the SKP probe The probe diameter is important in the SKP measurement because it affects the overall resolution of the measurement with smaller probes leading to improved resolution 10 11 On the other hand reducing the size of the probe causes an increase in fringing effects which reduces the sensitivity of the measurement by increasing the measurement of stray capacitances 10 The material used in the construction of the SKP probe is important to the quality of the SKP measurement 12 This occurs for a number of reasons Different materials have different work function values which will affect the contact potential measured Different materials have different sensitivity to humidity changes The material can also affect the resulting lateral resolution of the SKP measurement In commercial probes tungsten is used 13 though probes of platinum 14 copper 15 gold 16 and NiCr has been used 17 The probe to sample distance affects the final SKP measurement with smaller probe to sample distances improving the lateral resolution 11 and the signal to noise ratio of the measurement 18 Furthermore reducing the SKP probe to sample distance increases the intensity of the measurement where the intensity of the measurement is proportional to 1 d2 where d is the probe to sample distance 19 The effects of changing probe to sample distance on the measurement can be counteracted by using SKP in constant distance mode Work function editThe Kelvin probe force microscope or Kelvin force microscope KFM is based on an AFM set up and the determination of the work function is based on the measurement of the electrostatic forces between the small AFM tip and the sample The conducting tip and the sample are characterized by in general different work functions which represent the difference between the Fermi level and the vacuum level for each material If both elements were brought in contact a net electric current would flow between them until the Fermi levels were aligned The difference between the work functions is called the contact potential difference and is denoted generally with VCPD An electrostatic force exists between tip and sample because of the electric field between them For the measurement a voltage is applied between tip and sample consisting of a DC bias VDC and an AC voltage VAC sin wt of frequency w V V D C V C P D V A C sin w t displaystyle V V DC V CPD V AC cdot sin omega t nbsp Tuning the AC frequency to the resonant frequency of the AFM cantilever results in an improved sensitivity The electrostatic force in a capacitor may be found by differentiating the energy function with respect to the separation of the elements and can be written as F 1 2 d C d z V 2 displaystyle F frac 1 2 frac dC dz V 2 nbsp where C is the capacitance z is the separation and V is the voltage each between tip and surface Substituting the previous formula for voltage V shows that the electrostatic force can be split up into three contributions as the total electrostatic force F acting on the tip then has spectral components at the frequencies w and 2w F F D C F w F 2 w displaystyle F F DC F omega F 2 omega nbsp The DC component FDC contributes to the topographical signal the term Fw at the characteristic frequency w is used to measure the contact potential and the contribution F2w can be used for capacitance microscopy F D C d C d z 1 2 V D C V C P D 2 1 4 V A C 2 displaystyle F DC frac dC dz left frac 1 2 V DC V CPD 2 frac 1 4 V AC 2 right nbsp F w d C d z V D C V C P D V A C sin w t displaystyle F omega frac dC dz V DC V CPD V AC sin omega t nbsp F 2 w 1 4 d C d z V A C 2 cos 2 w t displaystyle F 2 omega frac 1 4 frac dC dz V AC 2 cos 2 omega t nbsp Contact potential measurements editFor contact potential measurements a lock in amplifier is used to detect the cantilever oscillation at w During the scan VDC will be adjusted so that the electrostatic forces between the tip and the sample become zero and thus the response at the frequency w becomes zero Since the electrostatic force at w depends on VDC VCPD the value of VDC that minimizes the w term corresponds to the contact potential Absolute values of the sample work function can be obtained if the tip is first calibrated against a reference sample of known work function 20 Apart from this one can use the normal topographic scan methods at the resonance frequency w independently of the above Thus in one scan the topography and the contact potential of the sample are determined simultaneously This can be done in at least two different ways 1 The topography is captured in AC mode which means that the cantilever is driven by a piezo at its resonant frequency Simultaneously the AC voltage for the KPFM measurement is applied at a frequency slightly lower than the resonant frequency of the cantilever In this measurement mode the topography and the contact potential difference are captured at the same time and this mode is often called single pass 2 One line of the topography is captured either in contact or AC mode and is stored internally Then this line is scanned again while the cantilever remains on a defined distance to the sample without a mechanically driven oscillation but the AC voltage of the KPFM measurement is applied and the contact potential is captured as explained above It is important to note that the cantilever tip must not be too close to the sample in order to allow good oscillation with applied AC voltage Therefore KPFM can be performed simultaneously during AC topography measurements but not during contact topography measurements Applications editThe Volta potential measured by SKP is directly proportional to the corrosion potential of a material 21 as such SKP has found widespread use in the study of the fields of corrosion and coatings In the field of coatings for example a scratched region of a self healing shape memory polymer coating containing a heat generating agent on aluminium alloys was measured by SKP 22 Initially after the scratch was made the Volta potential was noticeably higher and wider over the scratch than over the rest of the sample implying this region is more likely to corrode The Volta potential decreased over subsequent measurements and eventually the peak over the scratch completely disappeared implying the coating has healed Because SKP can be used to investigate coatings in a non destructive way it has also been used to determine coating failure In a study of polyurethane coatings it was seen that the work function increases with increasing exposure to high temperature and humidity 23 This increase in work function is related to decomposition of the coating likely from hydrolysis of bonds within the coating Using SKP the corrosion of industrially important alloys has been measured citation needed In particular with SKP it is possible to investigate the effects of environmental stimulus on corrosion For example the microbially induced corrosion of stainless steel and titanium has been examined 24 SKP is useful to study this sort of corrosion because it usually occurs locally therefore global techniques are poorly suited Surface potential changes related to increased localized corrosion were shown by SKP measurements Furthermore it was possible to compare the resulting corrosion from different microbial species In another example SKP was used to investigate biomedical alloy materials which can be corroded within the human body In studies on Ti 15Mo under inflammatory conditions 25 SKP measurements showed a lower corrosion resistance at the bottom of a corrosion pit than at the oxide protected surface of the alloy SKP has also been used to investigate the effects of atmospheric corrosion for example to investigate copper alloys in marine environment 26 In this study Kelvin potentials became more positive indicating a more positive corrosion potential with increased exposure time due to an increase in thickness of corrosion products As a final example SKP was used to investigate stainless steel under simulated conditions of gas pipeline 27 These measurements showed an increase in difference in corrosion potential of cathodic and anodic regions with increased corrosion time indicating a higher likelihood of corrosion Furthermore these SKP measurements provided information about local corrosion not possible with other techniques SKP has been used to investigate the surface potential of materials used in solar cells with the advantage that it is a non contact and therefore a non destructive technique 28 It can be used to determine the electron affinity of different materials in turn allowing the energy level overlap of conduction bands of differing materials to be determined The energy level overlap of these bands is related to the surface photovoltage response of a system 29 As a non contact non destructive technique SKP has been used to investigate latent fingerprints on materials of interest for forensic studies 30 When fingerprints are left on a metallic surface they leave behind salts which can cause the localized corrosion of the material of interest This leads to a change in Volta potential of the sample which is detectable by SKP SKP is particularly useful for these analyses because it can detect this change in Volta potential even after heating or coating by for example oils SKP has been used to analyze the corrosion mechanisms of schreibersite containing meteorites 31 32 The aim of these studies has been to investigate the role in such meteorites in releasing species utilized in prebiotic chemistry In the field of biology SKP has been used to investigate the electric fields associated with wounding 33 and acupuncture points 34 In the field of electronics KPFM is used to investigate the charge trapping in High k gate oxides interfaces of electronic devices 35 36 37 See also editScanning probe microscopy Surface photovoltageReferences edit M Nonnenmacher M P O Boyle H K Wickramasinghe 1991 Kelvin probe force microscopy PDF Appl Phys Lett 58 25 2921 Bibcode 1991ApPhL 58 2921N doi 10 1063 1 105227 Archived from the original free download pdf on 2009 09 20 Fujihira Masamichi 1999 Kelvin Probe Force Microscopy of Molecular Surfaces Annual Review of Materials Science 29 1 353 380 Bibcode 1999AnRMS 29 353F doi 10 1146 annurev matsci 29 1 353 ISSN 0084 6600 Melitz Wilhelm Shen Jian Kummel Andrew C Lee Sangyeob 2011 Kelvin probe force microscopy and its application Surface Science Reports 66 1 1 27 Bibcode 2011SurSR 66 1M doi 10 1016 j surfrep 2010 10 001 ISSN 0167 5729 Kelvin Lord 1898 V Contact electricity of metals The London Edinburgh and Dublin Philosophical Magazine and Journal of Science 46 278 82 120 doi 10 1080 14786449808621172 ISSN 1941 5982 Zisman W A 1932 A New Method of Measuring Contact Potential Differences in Metals Review of Scientific Instruments 3 7 367 370 Bibcode 1932RScI 3 367Z doi 10 1063 1 1748947 ISSN 0034 6748 Rohwerder Michael Turcu Florin 2007 High resolution Kelvin probe microscopy in corrosion science Scanning Kelvin probe force microscopy SKPFM versus classical scanning Kelvin probe SKP Electrochimica Acta 53 2 290 299 doi 10 1016 j electacta 2007 03 016 Cheran Larisa Emilia Johnstone Sherri Sadeghi Saman Thompson Michael 2007 01 19 Work function measurement by high resolution scanning Kelvin nanoprobe Measurement Science and Technology 18 3 567 578 Bibcode 2007MeScT 18 567C doi 10 1088 0957 0233 18 3 005 ISSN 0957 0233 S2CID 123457387 Surplice N A D Arcy R J 1970 A critique of the Kelvin method of measuring work functions Journal of Physics E Scientific Instruments 3 7 477 482 doi 10 1088 0022 3735 3 7 201 ISSN 0022 3735 Wagner Christian Green Matthew F B Leinen Philipp Deilmann Thorsten Kruger Peter Rohlfing Michael Temirov Ruslan Tautz F Stefan 2015 07 06 Scanning Quantum Dot Microscopy Physical Review Letters 115 2 026101 arXiv 1503 07738 Bibcode 2015PhRvL 115b6101W doi 10 1103 PhysRevLett 115 026101 ISSN 0031 9007 PMID 26207484 S2CID 1720328 a b Wicinski Mariusz Burgstaller Wolfgang Hassel Achim Walter 2016 Lateral resolution in scanning Kelvin probe microscopy Corrosion Science 104 1 8 doi 10 1016 j corsci 2015 09 008 a b McMurray H N Williams G 2002 Probe diameter and probe specimen distance dependence in the lateral resolution of a scanning Kelvin probe Journal of Applied Physics 91 3 1673 1679 Bibcode 2002JAP 91 1673M doi 10 1063 1 1430546 ISSN 0021 8979 Huber Silvia Wicinski Mariusz Hassel Achim Walter 2018 Suitability of Various Materials for Probes in Scanning Kelvin Probe Measurements Physica Status Solidi A 215 15 1700952 Bibcode 2018PSSAR 21500952H doi 10 1002 pssa 201700952 High Resolution Scanning Kelvin Probe Bio Logic Science Instruments Retrieved 2019 05 17 Hansen Douglas C Hansen Karolyn M Ferrell Thomas L Thundat Thomas 2003 Discerning Biomolecular Interactions Using Kelvin Probe Technology Langmuir 19 18 7514 7520 doi 10 1021 la034333w ISSN 0743 7463 Dirscherl Konrad Baikie Iain Forsyth Gregor Heide Arvid van der 2003 Utilisation of a micro tip scanning Kelvin probe for non invasive surface potential mapping of mc Si solar cells Solar Energy Materials and Solar Cells 79 4 485 494 doi 10 1016 S0927 0248 03 00064 3 Stratmann M 1987 The investigation of the corrosion properties of metals covered with adsorbed electrolyte layers A new experimental technique Corrosion Science 27 8 869 872 doi 10 1016 0010 938X 87 90043 6 Nazarov A P Thierry D 2001 Study of the Carbon Steel Alkyd Coating Interface with a Scanning Vibrating Capacitor Technique Protection of Metals 37 2 108 119 doi 10 1023 a 1010361702449 ISSN 0033 1732 S2CID 92117439 Height tracking with the SKP370 or SKP470 module PDF Bio Logic Science Instruments Retrieved 2019 05 17 Wapner K Schoenberger B Stratmann M Grundmeier G 2005 Height Regulating Scanning Kelvin Probe for Simultaneous Measurement of Surface Topology and Electrode Potentials at Buried Polymer Metal Interfaces Journal of the Electrochemical Society 152 3 E114 Bibcode 2005JElS 152E 114W doi 10 1149 1 1856914 Fernandez Garrillo P A Grevin B Chevalier N Borowik L 2018 Calibrated work function mapping by Kelvin probe force microscopy PDF Review of Scientific Instruments 89 4 043702 Bibcode 2018RScI 89d3702F doi 10 1063 1 5007619 PMID 29716375 SKP imaging example of a corroded Zn plated Fe sample PDF Bio Logic Science Instruments Retrieved 2019 05 17 Fan Weijie Zhang Yong Li Weihua Wang Wei Zhao Xiaodong Song Liying 2019 Multi level self healing ability of shape memory polyurethane coating with microcapsules by induction heating Chemical Engineering Journal 368 1033 1044 doi 10 1016 j cej 2019 03 027 S2CID 104432686 Borth David J Iezzi Erick B Dudis Douglas S Hansen Douglas C 2019 Nondestructive Evaluation of Urethane Ester Coating Systems Using the Scanning Kelvin Probe Technique Corrosion 75 5 457 464 doi 10 5006 3020 ISSN 0010 9312 S2CID 105314795 Zhang Dawei Zhou Feichi Xiao Kui Cui Tianyu Qian Hongchong Li Xiaogang 2015 Microbially Influenced Corrosion of 304 Stainless Steel and Titanium by P variotii and A niger in Humid Atmosphere Journal of Materials Engineering and Performance 24 7 2688 2698 Bibcode 2015JMEP 24 2688Z doi 10 1007 s11665 015 1558 2 ISSN 1059 9495 S2CID 137116966 Szklarska M Dercz G Kubisztal J Balin K Losiewicz B 2016 Semi Conducting Properties of Titanium Dioxide Layer on Surface of Ti 15Mo Implant Alloy in Biological Milieu Acta Physica Polonica A 130 4 1085 1087 Bibcode 2016AcPPA 130 1085S doi 10 12693 APhysPolA 130 1085 ISSN 0587 4246 Kong Decheng Dong Chaofang Ni Xiaoqing Man Cheng Xiao Kui Li Xiaogang 2018 Insight into the mechanism of alloying elements Sn Be effect on copper corrosion during long term degradation in harsh marine environment Applied Surface Science 455 543 553 Bibcode 2018ApSS 455 543K doi 10 1016 j apsusc 2018 06 029 S2CID 102769318 Jin Z H Ge H H Lin W W Zong Y W Liu S J Shi J M 2014 Corrosion behaviour of 316L stainless steel and anti corrosion materials in a high acidified chloride solution Applied Surface Science 322 47 56 Bibcode 2014ApSS 322 47J doi 10 1016 j apsusc 2014 09 205 Dirscherl Konrad Baikie Iain Forsyth Gregor Heide Arvid van der 2003 Utilisation of a micro tip scanning Kelvin probe for non invasive surface potential mapping of mc Si solar cells Solar Energy Materials and Solar Cells 79 4 485 494 doi 10 1016 s0927 0248 03 00064 3 ISSN 0927 0248 Liu Xiangyang Zheng Haiwu Zhang Jiwei Xiao Yin Wang Zhiyong 2013 Photoelectric properties and charge dynamics for a set of solid state solar cells with Cu4Bi4S9 as the absorber layer Journal of Materials Chemistry A 1 36 10703 doi 10 1039 c3ta11830d ISSN 2050 7488 Williams Geraint McMurray H N 2008 Human Fingerprint Metal Interactions Studied Using a Scanning Kelvin Probe ECS Transactions Washington DC ECS 11 22 81 89 Bibcode 2008ECSTr 11v 81W doi 10 1149 1 2925265 S2CID 98393112 Bryant David E Greenfield David Walshaw Richard D Evans Suzanne M Nimmo Alexander E Smith Caroline L Wang Liming Pasek Matthew A Kee Terence P 2009 Electrochemical studies of iron meteorites phosphorus redox chemistry on the early Earth International Journal of Astrobiology 8 1 27 36 Bibcode 2009IJAsB 8 27B doi 10 1017 S1473550408004345 ISSN 1473 5504 S2CID 97821022 Bryant David E Greenfield David Walshaw Richard D Johnson Benjamin R G Herschy Barry Smith Caroline Pasek Matthew A Telford Richard Scowen Ian 2013 Hydrothermal modification of the Sikhote Alin iron meteorite under low pH geothermal environments A plausibly prebiotic route to activated phosphorus on the early Earth Geochimica et Cosmochimica Acta 109 90 112 Bibcode 2013GeCoA 109 90B doi 10 1016 j gca 2012 12 043 Nuccitelli Richard Nuccitelli Pamela Ramlatchan Samdeo Sanger Richard Smith Peter J S 2008 Imaging the electric field associated with mouse and human skin wounds Wound Repair and Regeneration 16 3 432 441 doi 10 1111 j 1524 475X 2008 00389 x ISSN 1067 1927 PMC 3086402 PMID 18471262 Gow Brian J Cheng Justine L Baikie Iain D Martinsen Orjan G Zhao Min Smith Stephanie Ahn Andrew C 2012 Electrical Potential of Acupuncture Points Use of a Noncontact Scanning Kelvin Probe Evidence Based Complementary and Alternative Medicine 2012 632838 doi 10 1155 2012 632838 ISSN 1741 427X PMC 3541002 PMID 23320033 Tzeng S D Gwo S 2006 07 15 Charge trapping properties at silicon nitride silicon oxide interface studied by variable temperature electrostatic force microscopy Journal of Applied Physics 100 2 023711 023711 9 Bibcode 2006JAP 100b3711T doi 10 1063 1 2218025 ISSN 0021 8979 Khosla Robin Kumar Pawan Sharma Satinder K December 2015 Charge Trapping and Decay Mechanism in Post Deposition Annealed Er2O3 MOS Capacitors by Nanoscopic and Macroscopic Characterization IEEE Transactions on Device and Materials Reliability 15 4 610 616 doi 10 1109 TDMR 2015 2498310 ISSN 1530 4388 S2CID 33548746 Khosla Robin Rolseth Erlend Granbo Kumar Pawan Vadakupudhupalayam Senthil Srinivasan Sharma Satinder K Schulze Jorg March 2017 Charge Trapping Analysis of Metal Al 2 O 3 SiO 2 Si Gate Stack for Emerging Embedded Memories IEEE Transactions on Device and Materials Reliability 17 1 80 89 doi 10 1109 TDMR 2017 2659760 ISSN 1530 4388 S2CID 24247825 External links editMasaki Takihara 9 December 2008 Kelvin probe force microscopy Takahashi Lab Institute of Industrial Science University of Tokyo Archived from the original on 29 October 2012 Retrieved 29 February 2012 Full description of the principles with good illustrations to aid comprehension Transport measurements by Scanning Probe Microscopy Introduction to Kelvin Probe Force Microscopy KPFM Dynamic Kelvin Probe Force Microscopy Kelvin Probe Force Microscopy of Lateral Devices Kelvin Probe Force Microscopy in Liquids Current voltage Measurements in Scanning Probe Microscopy Dynamic IV measurements in SPM Retrieved from https en wikipedia org w index php title Kelvin probe force microscope amp oldid 1170454267, 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