Introduction to Atomic Force Microscopy

This chapter provides an overview of the atomic force microscope (AFM) system. It begins with a broad discussion on a list of tools available for imaging at micro-/nanoscale. Subsequently, the book’s scope, objectives, and chapter topics are outlined. The discussion centers around the operational principles and imaging capabilities of AFMs without going into specific implementation details. Fundamental aspects such as modes of operation, probe-sample interactions, experimental procedures, and data analysis are explored. This knowledge base lays a solid foundation for the readers to design experiments, capture AFM images, and interpret the results.

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References

1. Gordon E Moore et al. Cramming more components onto integrated circuits. 1965. Google Scholar
2. Gerd Binnig and Heinrich Rohrer. “Scanning tunneling microscopy”. In: Surface science 126.1-3 (1983), pp. 236–244. Google Scholar
3. Jerry Tersoff and Donald R Hamann. “Theory of the scanning tunneling microscope”. In: Physical Review B 31.2 (1985), p. 805. Google Scholar
4. Johann Coraux et al. “Structural coherency of graphene on Ir (111)”. In: Nano letters 8.2 (2008), pp. 565–570. Google Scholar
5. Donald M Eigler and Erhard K Schweizer. “Positioning single atoms with a scanning tunnelling microscope”. In: Nature 344.6266 (1990), pp. 524–526. Google Scholar
6. G. Binnig et al. “Atomic Force Microscope”. In: Phys. Rev. Lett. 56 (Mar. 1986), pp. 930–933. Google Scholar
7. Oscar Custance, Ruben Perez, and Seizo Morita. “Atomic force microscopy as a tool for atom manipulation”. In: Nature nanotechnology 4.12 (2009), p. 803. Google Scholar
8. Fangzhou Xia et al. “AFM SMILER: A Scale Model Interactive Learning Extended Reality Toolkit for Atomic Force Microscopy Created With Digital Twin Technology”. In: IEEE/ASME Transactions on Mechatronics (2023). Google Scholar
9. Fangzhou Xia. “Design and Control of Versatile High-speed and Large- range Atomic Force Microscopes”. PhD thesis. Massachusetts Institute of Technology, 2020. Google Scholar
10. Fangzhou Xia* and Kamal Youcef-Toumi. “Review: Advanced Atomic Force Microscopy for Biomedical Research”. In: Biosensors 12.12 (2022), p. 1116. Google Scholar
11. Yaxin Song and Bharat Bhushan. “Atomic force microscopy dynamic modes: modeling and applications”. In: Journal of Physics: Condensed Matter 20.22 (May 2008), p. 225012. Google Scholar
12. Jian Shi et al. Method and apparatus of using peak force tapping mode to measure physical properties of a sample. US Patent 8,650,660. Feb. 2014. Google Scholar
13. G. Smolyakov et al. “AFM> PeakForce QNM> mode: Evidencing nanometer-scale mechanical properties of chitin-silica hybrid nanocomposites”. In: Carb-ohydrate Polymers 151 (2016), pp. 373–380. issn : 0144-8617. Google Scholar
14. P. Biczysko et al. “Contact atomic force microscopy using piezoresistive cantilevers in load force modulation mode”. In: Ultramicroscopy 184 (Sept. 2017). Google Scholar
15. Fangzhou Xia, I Soltani Bozchalooi, and Kamal Youcef-Toumi. “Induced vibration contact detection for minimizing cantilever tip-sample interaction forces in jumping mode atomic force microscopy”. In: 2017 American Control Conference (ACC). IEEE. 2017, pp. 4141–4146. Google Scholar
16. A Rosa-Zeiser et al. “The simultaneous measurement of elastic, electrostatic and adhesive properties by scanning force microscopy: pulsed-force mode operation”. In: Measurement Science and Technology 8.11 (1997), p. 1333. Google Scholar
17. Mathias Holz et al. “Correlative Microscopy and Nanofabrication with AFM Integrated with SEM”. In: Microscopy Today 27.6 (Nov. 2019), pp. 24–30. issn : 151-9295. Note: ISSN should be in smallcaps Google Scholar
18. Pier Carlo Braga and Davide Ricci. Atomic force microscopy in biomedical research: methods and protocols. Springer, 2011. Google Scholar
19. David Nečas and Petr Klapetek. “Gwyddion: an open-source software for SPM data analysis”. In: Open Physics 10.1 (2012), pp. 181–188. Google Scholar

Author information

Authors and Affiliations

1. Mechanical Engineering Department, Physics Department, Massachusetts Institute of Technology, Cambridge, MA, USA Fangzhou Xia
2. Production and Precision Metrology, Ilmenau University of Technology, Ilmenau, Germany Ivo W. Rangelow
3. Mechanical Engineering Department, Massachusetts Institute of Technology, Cambridge, MA, USA Kamal Youcef-Toumi

1. Fangzhou Xia