  | |||||||||||||||||||
|
|||||||||||||||||||
|
|||||||||||||||||||
|
|||||||||||||||||||
|
|||||||||||||||||||
| Journal Home | |
| Current Issue | |
| AOP | |
| Archive | |
| |
| |
THIS ARTICLE  | |
| |
| Download PDF | |
| References | |
| |
| |
| |
| Export citation | |
| Export references | |
| |
| |
| |
| Send to a friend | |
| |
| |
| |
| More articles like this | |
| |
| |
| |
| Table of Contents | |
| < Previous | Next > | |
| |
 |
 |
| Nature 320, 342 - 344 (27 March 1986); doi:10.1038/320342a0 |
|
Bubble raft model for indentation with adhesion
J. M. Georges, G. Meille, J. L. Loubet & A. M. Tolen
Laboratoire de Technologic des Surfaces, Ecole Centrale de Lyon, 36 avenue Guy de Collongue, CNRS UA 85, BP 163, 69131 Ecully Cedex, France
Indentation hardness tests are now widely used to measure the mechanical properties of solid surfaces1−3. Recent developments of this technique4,5 permit the analysis of the outermost 10 nm of materials. Experimental and theoretical questions arise regarding the physical and mechanical processes involved in such small indentations. We describe here an indentation experiment on a microscopic scale, using soap bubbles blown onto a water surface. Bubble rafts provide a simple two-dimensional model for indentation behaviour; as for other materials, their behaviour is governed by two principal attraction−repulsion forces6, and by geometrical constraints. A crystalline two-dimensional lattice is obtained by using bubbles of uniform size7−9, whereas bubbles of two sizes give an amorphous structure10,11. Indentation can be represented by the contact between a triangular crystalline raft and a rectangular crystalline raft bordered by an amorphous layer. The flow of the materials, which is dependent on both adhesion and the force between the two rafts, can be analysed during the experiment.
| 1. | Tabor, D. The Hardness of Metals (Clarendon, Oxford, 1951). |
| 2. | Atkins, A. G. Metal Sci. J. 16, 127−137 (1982). |
| 3. | Johnson, K. L. J. Mech. Phys. Solids 18, 115−126 (1970). | Article | ISI | |
| 4. | Pollock, H. M., Maugis, D. & Barquins, M. IMS/ASTM Microindentation Hardness Testing Symp. 1984 (ASTM, in the press). |
| 5. | Tonck, A., Loubet, J. L. & Georges, J. M. ASLE Preprint no.85 TC-2A-1, Tribology Conf., Atlanta (1985). |
| 6. | Bragg, L. & Nye, J. F. Proc. R. Soc. A190, 474−481 (1949). | ISI | |
| 7. | Bragg, L. & Lomer, W. M. Proc. R. Soc. A196, 171−181 (1949). | ISI | |
| 8. | Lomer, W. M. Proc. R. Soc. A196, 182−194 (1949). | ISI | |
| 9. | Argon, A. S. & Shi, L. T. in Proc. Fall Meet. Metall. Soc. AIME (ed. Viteck, V.) 279−303 (1982). |
| 10. | Georges, J. M. & Meille, G. Proc. JSLE int. Tribology Conf., Tokyo, 885−890 (1985). | ChemPort | |
| 11. | Maeda, K. & Takeuchi, S. Phil. Mag. A44, 643−656 (1981). | ISI | ChemPort | |
| 12. | Simpson, A. W. & Hodkinson, P. Nature 237, 320−322 (1972). | ISI | ChemPort | |
| 13. | Maeda, K. & Takeuchi, S. Phys. Status Solidi A49, 685−696 (1978). | ISI | ChemPort | |
© 1986 Nature Publishing Group
Privacy Policy
