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Imaging Of Hierarchically Structured Materials

Published online by Cambridge University Press:  21 February 2011

Mehmet Sarikaya  and
Ilhan A. Aksay
Mehmet Sarikaya
Affiliation:
Department of Materials Science and Engineering, and Advanced Materials Technology Center, The Washington Technology Center, University of Washington, Seattle, WA 98195
Ilhan A. Aksay
Affiliation:
Department of Materials Science and Engineering, and Advanced Materials Technology Center, The Washington Technology Center, University of Washington, Seattle, WA 98195
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Abstract

We describe techniques used to characterize hierarchically structured synthetic and biological materials. These techniques decipher the structures through the dimensional spectrum from the molecular and atomic scales (10.−10 m) to the macro scales (10−3 m) where the overall shape of the material emerges. Techniques used to image surfaces and internal structures can be categorized according to their wavelength and thus spatial resolution as light, x-ray, and electron microscopy. We also discuss newly emerging microscopy techniques that image surfaces at the atomic level without a focusing lens, such as scanning tunneling and atomic force microscopies, with the aid of field ion microscope and scanned probe microscopes. Transmission electron microscopy (TEM), a unique tool for multipurpose imaging, provides structural information through direct imaging, diffraction, and spectroscopic analysis. We illustrate the major TEM techniques used to analyze structural hierarchy with examples of synthetic and biological materials. We also describe light optical microscopy and scanning probe microscopy techniques, which cover the opposite ranges of the dimensional spectrum at the micrometer and subangstrom levels.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 255: Symposium Z – Hierarchically Structured Materials , 1991 , 293
Copyright
Copyright © Materials Research Society 1992

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References

1. Smith, C. S., “Structural Hierarchy in Science, Art, and History,,” in Aesthetics in Science, Wechsler, J. (ed.) (MIT Press, Cambridge, Massachusetts, 1978), pp. 953.Google Scholar
2. Phase Transformations, edited by Aaronson, H. I. and Wayman, C. M. (American Society of Metals, Metals Park, Ohio, 1982).Google Scholar
3. Kroger, F. A., The Chemistry ofImperfect Crystals, Vol.2 (North-Holland, Amsterdam, 1974).Google Scholar
4. (a) Aksay, I. A., “Molecular and Colloidal Engineering of Ceramics,” Ceramics International, 17 [5] 267–74 (1991); (b) M. Sarikaya, “Atomic Resolution Microscopies in Materials,” in Advanced Characterization techniques in Ceramics, Ceramic Transactions, Vol. 5 (American Ceramic Society, Westerville, Ohio, 1990), pp. 247–86.Google Scholar
5. Mathews, C. K. and Holde, K. E.van, Biochemistry (Benjamin/Cummins Publ., Redwood City, California, 1990).Google Scholar
6. Baer, E., Cassidy, J. J., and Hiltner, A., “Hierarchical Structure of Collagen and Its Relationship to the Physical Properties of Tendon,” Chapter 9 in Collagen: Biochemistry and Biomechanics, Vol.11, edited by Nimi, M. E. (CRC Press, Boca Raton, Florida, 1988), pp. 177–99.Google Scholar
7. Glimcher, M. J., “On the Form and Function of Bone; from Molecules to Organs,” The Chemistry and Function of Mineralized Tissues, edited by Veis, A. (Elsevier, Amsterdam, 1981), pp. 617–73.Google Scholar
8. Weiner, S. and Traub, W., “Mineralized Tendon, Bone, and Dentin,” Connect. Tissue. Res., 27 [2–3] 86 (1992).Google Scholar
9. Lowenstam, H. A. and Weiner, S., On Biomineralization (Oxford University Press, New York, 1989).Google Scholar
10. Liu, J., Sarikaya, M., and Aksay, I. A., “A Hierarchically Structured Model Composite: A TEM Study of the Hard Tissue of Red Abalone,” this volume.Google Scholar
11. Currey, J. D., “Biological Composites,” J. Mater. Edu., 9 [1–2] 118296 (1987).Google Scholar
12. Jackson, A. P., Vincent, J. F. V., and Turner, R. M., “The Mechanical Design of Nacre,” Proc. Roy. Soc., London, B234, 415–40 (1988).Google Scholar
13. Sarikaya, M. and Aksay, I. A., “Nacre of Abalone Shell: A Natural Multifunctional Nanolaminated Ceramic-Polymer Composite Material,” Chapter 1 in Structure, Cellular Synthesis, and Assembly of Biopolymers, edited by Case, S. (Springer-Verlag, New York, 1992).Google Scholar
14. Liu, J., Sarikaya, M., and Aksay, I. A., unpublished work.Google Scholar
15. Sibilia, J. P., Materials Characterizationa nd ChemicalAnalysis(VCH, New York, 1988).Google Scholar
16. Hooke, R., Micrographia (Royal Society, London, 1665).Google Scholar
17. Sarikaya, M., Ph.D. Thesis (University of California, Berkeley, LBL Rep. # 15211, 1982).Google Scholar
18. (a) Sarikaya, M. and Thomas, G., “Lath Martensites in Low Carbon Steels, J. Phys., Colleque (4) supp. 12, Tome 43, C4–563–68 (1982); (b) M. Sarikaya, H. Togushige, and G. Thomas, “Lath Martensite and Bainite in Low Alloy Steels,” in Proc. of Intl. Conf. on Martensitic Transformations (Japan Institute of Metals, Tokyo, 1986), pp. 613–18.Google Scholar
19. The Handbook of Biological Confocal Microscopy, edited by J. Pawley (IMR, Madison, Wisconsin, 1989).Google Scholar
20. lsaacson, M., “Resolution in Near-Field Optical Microscopy,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
21. Howels, M., Kirz, J., and Sayre, D., “X-ray Microscopes,” Sci. Amer., 264 [2] 8894 (1991).Google Scholar
22. Crewe, A. V., Langmore, J. P., and Isaacson, M., “Resolution and Contrast in the Scanning Transmission Electron Microscope,” Chapter 4 in Physical Aspects of Electron Microscopy and Microbeam Analysis, edited by Siegel, B. M. and Beaman, D. K. (Wiley, New York, 1975), pp. 4762.Google Scholar
23. Jacobsen, C., Kirz, J., and Williams, S., “Resolution in X-ray Microscopes,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
24. Practical Scanning Electron Microscopy: Electron and Ion Microanalysis, Goldstein, J. I. and edited by Yakowitz, H. (Plenum, New York, 1975).Google Scholar
25. Joy, D. C. and Pawley, J., “Resolution in the SEM,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
26. Pennycook, S. J., “Z-Contrast STEM for Materials Science,” Ultramicroscopy, 30, 5869 (1989).Google Scholar
27. Reimer, L., Transmission Electron Microscopy (Springer-Verlag, Berlin, 1984).Google Scholar
28. Sarikaya, M. and Howe, J. M., “Resolution in CTEM,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
29. Spence, J. C. H., Experimental High Resolution Electron Microscopy (Oxford University Press, Oxford, 1986).Google Scholar
30. O'Keefe, M. A., “Resolution in High Resolution Electron Microscopy,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
31. Krivanek, O. L., “High Resolution Imaging of Grain Boundaries and Interfaces,” Chemica Scripta, 14, 213–20 (1979).Google Scholar
32. Cowley, J. M. and Smith, D. J., “High Resolution Transmission Electron Microscopy,” Acta. Cryst., A 43, 739–48 (1989).Google Scholar
33. Steeds, J. W., “Convergent Beam Electron Diffraction,” in Introduction to Analytical Electron Microscopy, edited by Hren, J. J., Goldstein, J. I., and Joy, D. C. (Plenum, New York, 1979), pp. 387422.Google Scholar
34. Tanaka, M., Sito, R., and Sekii, H., “Point Group Determination by Convergent Beam Electron Diffraction,” Acta. Cryst., A39, 357–68 (1983).Google Scholar
35. Steeds, J. W. and Vincent, R., “Use of High Symmetry Zone Axis in Electron Diffraction in Determining Crystal Point and Space Groups,” J. App. Cryst., 16, 317–24 (1983).Google Scholar
36. Goldstein, J. I., “Principles of Thin Film Microanalysis,” Chapter 3, pp. 83–120, and N. Zaluzec, “Quantitative X-ray Microanalysis: Instrumental Considerations and Applications to Materials Science,” Chapter 4, pp. 121–68, in Introduction to Analytical Electron Microscopy, edited by J. J. Hren, J. I. Goldstein, and D. C. Joy (Plenum, New York, 1979).Google Scholar
37. Williams, D. B. et al., “Resolution in Energy Dispersive X-ray Spectroscopy,” in Resolution in the Microscope, Ultramicroscopy, edited by special issue, Sarikaya, M., in press (1992).Google Scholar
38. Egerton, R. F., Electron Energy Loss Spectroscopy in the Electron Microscope (Plenum, New York, 1986).Google Scholar
39. Brydson, R., “Interpretation of Near Edge Structure in the Electron Energy Loss Spectrum,” EMSA Bulletin, 21 [2] 5767 (1991).Google Scholar
40. Stern, E. A. and Hcald, S. M., “Basic Principles and Applications of EXAFS,” Chapter 10 in Handbook on Synchrotron Radiation, Vol.1, edited by Koch, E. E. (North-Holland, Amsterdam, 1983).Google Scholar
41. Cisillag, S., Johnson, D. A., and Stern, E. A., “Extended Energy Loss Fine Structure Studies in the Electron Microscope,” in EXAFS Spectroscopy: Techniques and Applications, edited by Teo, F. K. and Joy, D. C. (Plenum, New York, 1981), pp. 241–54.Google Scholar
42. Good, R. H. and Muller, E. W., ”Field Emission,” in Handbuch der physik, Vol.21 (Springer- Verlag, Berlin, 1956), pp. 176231.Google Scholar
43. Miller, M. K. and Smith, G. D. W., Atom Probe Microanalysis: Principles and Applications to Materials Research (Materials Research Society, Pittsburgh, Pennsylvania, 1989).Google Scholar
44. Grovenor, C. R. M. et al., “Ultrahigh-Resolution Chemical Analysis by Field-Ion Microscopy, Atom Probe, and Position Sensitive Atom Probe Techniques,” in Resolution in the Microscope, Ultramicroscopy, special issue, edited by Sarikaya, M., in press (1992).Google Scholar
45. Binnig, G. and Rohrer, H., “Scanning Tunneling Microscopy,” Heiv. Phys. Acta, 55, 726–35 (1992).Google Scholar
46. Birmig, G., Quate, C., and Gerber, C., “Atomic Force Microscope,” Phys. Rev. Lett., 56, 930–32 (1986).Google Scholar
47. Glovchenko, J. A., “The Tunneling Microscope: A New Look at the Atomic World,” Science, 232, 4853 (1986).Google Scholar
48. Hansma, P. K., Ellings, V. B., Marti, O., and Bracker, C. E., “Scanning Tunneling Microscopy and Atomic Tunneling Microscopy: Applications to Biology and Technology,” Science, 242, 209–16 (1988).CrossRefGoogle ScholarPubMed