Foundations of Chemistry

, Volume 8, Issue 1, pp 53–72 | Cite as

Gestalt Switch in Molecular Image Perception: The Aesthetic Origin of Molecular Nanotechnology in Supramolecular Chemistry

Article

Abstract

According to ‘standard histories’ of nanotechnology, the colorful pictures of atoms produced by scanning probe microscopists since the 1980s essentially inspired visions of molecular nanotechnology. In this paper, I provide an entirely different account that, nonetheless, refers to aesthetic inspiration, First, I argue that the basic idea of molecular nanotechnology, i.e., producing molecular devices, has been the goal of supramolecular chemistry that emerged earlier, without being called nanotechnology. Secondly, I argue that in supramolecular chemistry the production of molecular devices was inspired by an aesthetic phenomenon of gestalt switch, by certain images that referred to both molecules and ordinary objects, and thus symbolically bridged the two worlds. This opened up a new way of perceiving and drawing molecular images and new approaches to chemical synthesis. Employing Umberto Eco’s semiotic theory of aesthetics, I analyze the gestalt switch and the inspiration to build molecular devices and to develop a new sign language for supramolecular chemistry. More generally, I argue that aesthetic phenomena can play an important role in directing scientific research and that aesthetic theories can help understand such dynamics, such that they need to be considered in philosophy of science.

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References

  1. D. Baird and A. Shew. Probing the History of Scanning Tunneling Microscopy. In D. Baird, A. Nordmann and J. Schummer (Eds.), Discovering the Nanoscale, pp. 145–156. Amsterdam: IOS Press, 2004Google Scholar
  2. D. Baird, A. Nordmann and J. Schummer (Eds.), Discovering the Nanoscale. Amsterdam: IOS Press, 2004Google Scholar
  3. Balzani V, Credi A, Raymo F.M and Stoddart J.F (2000). Artificial Molecular Machines. Angewandte Chemie International Edition 39: 3348–91CrossRefGoogle Scholar
  4. Balzani V, Credi A and Venturi M (2003). Molecular Devices and Machines: A Journey into the Nanoworld. Wiley-VCH, WeinheimGoogle Scholar
  5. K.E. Drexler. Engines of Creation: The Coming Era of Nanotechnology. New York: Anchor Pr., Doubleday, 1986Google Scholar
  6. U. Eco. Opera aperta. Milano: Bompiani, 1962 (Engl. trans. as The Open Work, Hutchinson, 1989)Google Scholar
  7. U. Eco. La struttura assente, Bompiani, 1968.Google Scholar
  8. U. Eco. A Theory of Semiotics, Indiana University Press, 1976.Google Scholar
  9. A. Hessenbruch. Nanotechnology and the Negotiation of Novelty. In D. Baird, A. Nordmann and J. Schummer (Eds.), Discovering the Nanoscale, pp. 135–145. Amsterdam: IOS Press, 2004Google Scholar
  10. Lehn J.-M (1988). Supramolecular Chemistry - Scope and Perspectives: Molecules, Supermolecules and Molecular Devices (Nobel Lecture). Angewandte Chemie International Edition 27: 89–112CrossRefGoogle Scholar
  11. J.M. Lehn. Supramolecular Chemistry: Concepts and Perspectives, VCH, 1995.Google Scholar
  12. Lowey S (2003). So Near and Yet so Far from Understanding Molecular Motors: Recollections in Honor of John T. Edsall. Biophysical Chemistry 100: 171–175CrossRefGoogle Scholar
  13. C. Mody. How Probe Microscopists Became Nanotechnologists. In D. Baird, A. Nordmann and J. Schummer (Eds.), Discovering the Nanoscale, pp. 119–133. Amsterdam: IOS Press, 2004Google Scholar
  14. G. Schill. Catenanes, Rotaxanes, and Knots, Academic Press, 1971.Google Scholar
  15. Schummer J (1995). Ist die Chemie eine schöne Kunst: Zum Verhältnis von Kunst und Wissenschaft. Zeitschrift für Ästhetik and Allgemeine Kunstwissenschaft 40: 145–78 Google Scholar
  16. Schummer J (1998). The Chemical Core of Chemistry. I: A Conceptual Approach. Hyle 4: 129–162Google Scholar
  17. Schummer J (2003). Aesthetics of Chemical Products: Materials, Molecules and Molecular Models. Hyle 9: 73–104Google Scholar
  18. J. Schummer. Reading Nano: The Public Interest in Nanotechnology as Reflected in Book Purchase Patterns. Public Understanding of Science 14: 163–183, 2005Google Scholar
  19. J. Schummer. The Twisted History of Supramolecular Chemistry. (Unpublished Paper Presented at the Cain Conference “Nano Before There was Nano: Historical Perspectives on the Constituent Communities of Nanotechnology”, Chemical Heritage Foundation, Philadelphia, PA, 18–19 March 2005)Google Scholar
  20. F. Vögtle. Reizvolle Moleküle in der Organischen Chemie. Stuttgart: Teubner, 1989a (Engl. trans. as Fascinating Molecules in Organic Chemistry. Chichester: Wiley, 1992)Google Scholar
  21. F. Vögtle. Supramolekulare Chemie. Stuttgart. Teubner, 1989b (Engl. trans. as Supramolecular Chemistry, Chichester: Wiley, 1991)Google Scholar
  22. F. Vögtle. Cyclophan-Chemie. Stuttgart: Teubner, 1990 (Engl. trans. as Cyclophane Chemistry. Chichester: Wiley, 1993)Google Scholar
  23. F. Vögtle, L. Rossa and W, Bunzel. Schöne Moleküle in der organischen Chemie. Kontakte 2: 37–48, 1982 (partly reprinted in: Chemie für Labor und Betrieb 35: 178–179, 1984)Google Scholar

Copyright information

© Springer 2006

Authors and Affiliations

  1. 1.Department of PhilosophyTechnical University of DarmstadtDarmstadtGermany

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