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The Al–Si–C Phase Diagram and Its Use for Microstructural Analysis of MMCp and MMCf Composite Materials

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International Journal of Materials Research
Aus der Zeitschrift International Journal of Materials Research Band 92 Heft 9

Abstract

The microstructure and phase composition of metal matrix composites on the base of Al and Al–Si alloys, containing particles or fibres (MMCp, MMCf) of silicon carbide up to 20 wt.%, have been studied. The character of this interaction depends only slightly on the type of reinforcing elements. Using the literature and experimental data concerning the microstructure and phase composition of composite materials after prolonged holding at 700, 800, and 900 °C, the Al–Si–C phase diagram was corrected. The polythermal sections constructed both for equilibrium and nonequilibrium conditions allow to analyse the structure formation of MMCp and MMCf composite materials. The irreversible character of the chemical interaction in composite materials is often related to the retardation or the complete suppression of some reactions realized only under equilibrium conditions.

Keywords: Al–Si–C phase diagram; Composite materials; MMCp; MMCf
Dr. Andrey A. Aksenov Dept. of Physical Metallurgy Non-Ferrows Metals Moscow State Institute of Steel and Alloys Leninskiy prosp., 4, Moscow, Russia Fax: +7 095 236 31 29

References

1 Metcalf, A.: Composite Mater. 1 (1978) 437.Suche in Google Scholar

2 Aksenov, A.A.: Tsvetn. Metallurgiya 2 (1996) 34.Suche in Google Scholar

3 Lide, D.R. (Editor-in-Chief): CRC Handbook of Chemistry and Physics, 74th Edition, CRC Press, Boca Raton, FL (1992) 4.Suche in Google Scholar

4 The MERCK INDEX, 10th Edition, MERCK & Co (1983) 50.Suche in Google Scholar

5 Lee, J.-C.; Byun, J.-Y.; Oh, C.-S.; Seok, H.-K.; Lee, H.-I.: Acta mater. 45 (1997) 5303.10.1016/S1359-6454(97)84851-3Suche in Google Scholar

6 Mondolfo, L.F.: Aluminum Alloys: Structure and Properties, Butterworth, London (1976).Suche in Google Scholar

7 Schuster, J.C.: J. Phase Equilibria 12 (1991) 546.10.1007/BF02645066Suche in Google Scholar

8 Oden, L.; McCune, R.: Metall. Trans. A 18 (1987) 2005.10.1007/BF02647073Suche in Google Scholar

9 Barczak, V.J.: J. Amer. Ceram. Soc. 44 (1961) 299.10.1111/j.1151-2916.1961.tb15383.xSuche in Google Scholar

10 Kidwell, B.; Oden, L.; McCune, R.: J. Appl. Crystall. 17 (1984) 481.10.1107/S0021889884011973Suche in Google Scholar

11 Inoue, Z.; Inomata, Y.; Tanaka, H.; Kawabata: J. Mater. Sci. 15 (1980) 575.10.1007/BF00551719Suche in Google Scholar

12 Viala, J.; Fortier, P.; Boux, J.: J. Mater. Sci. 25 (1990) 1842.10.1007/BF01045395Suche in Google Scholar

13 Aksenov, A.; Churmukov, E.; Zolotorevskii, V.; Indenbaum, G.: Metally 1 (1995) 21.Suche in Google Scholar

14 Belov, N.A.; Gusev, A.Yu.; Eskin, D.G.: Z. Metallkd. 89 (1998) 618.Suche in Google Scholar

15 Belov, N.A.: Metally 1 (1995) 44.Suche in Google Scholar
Received: 2000-06-14
Published Online: 2022-01-12

© 2001 Carl Hanser Verlag, München

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial
  3. European Symposium on Nanomechanical Testing
  4. Aufsätze
  5. Comparison of Different Hardness Definitions Usable for Micro- and Nanoindentation
  6. Nanohardness Measurements for Industrial Applications
  7. Friction Studied with the Scanning Force Microscope
  8. Laser-Acoustics, a Method for Testing Coatings and Material Surfaces
  9. Nanoindentation Induced Acoustic Emission Monitoring of Native Oxide Fracture and Phase Transformations
  10. Deformation Curves of Ta-Silicide Thin Films Obtained in Cyclic Nanoindentation Experiments
  11. Pop-ins in Nanoindentations – the Initial Yield Point
  12. The Effect of Temperature and Strain Rate on the Hardness of Al and Al-Based Foams as Measured by Nanoindentation
  13. A Comparision of Nano-Hardness and Scratch-Resistance on Mohs Minerals
  14. Assisting an Experimental Investigation by Assessment and Use of a Thermodynamic Description for the Cd–Ge System
  15. Phase Equilibria and Thermodynamics in the Y2O3–Al2O3–SiO2 System
  16. The Constitution of Alloys in the Al-rich Corner of the Al–Si–Sm Ternary System
  17. The Al–Si–C Phase Diagram and Its Use for Microstructural Analysis of MMCp and MMCf Composite Materials
  18. Surface Segregation and Surface Tension in Liquid Fe–Cu Alloys
  19. Mitteilungen/Notifications
  20. Personelles/Personal
  21. Bücher/Books
  22. Tagungen/Conferences
https://doi.org/10.3139/ijmr-2001-0199
Schlagwörter für diesen Artikel
Al–Si–C phase diagram; Composite materials; MMCp; MMCf

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial
  3. European Symposium on Nanomechanical Testing
  4. Aufsätze
  5. Comparison of Different Hardness Definitions Usable for Micro- and Nanoindentation
  6. Nanohardness Measurements for Industrial Applications
  7. Friction Studied with the Scanning Force Microscope
  8. Laser-Acoustics, a Method for Testing Coatings and Material Surfaces
  9. Nanoindentation Induced Acoustic Emission Monitoring of Native Oxide Fracture and Phase Transformations
  10. Deformation Curves of Ta-Silicide Thin Films Obtained in Cyclic Nanoindentation Experiments
  11. Pop-ins in Nanoindentations – the Initial Yield Point
  12. The Effect of Temperature and Strain Rate on the Hardness of Al and Al-Based Foams as Measured by Nanoindentation
  13. A Comparision of Nano-Hardness and Scratch-Resistance on Mohs Minerals
  14. Assisting an Experimental Investigation by Assessment and Use of a Thermodynamic Description for the Cd–Ge System
  15. Phase Equilibria and Thermodynamics in the Y2O3–Al2O3–SiO2 System
  16. The Constitution of Alloys in the Al-rich Corner of the Al–Si–Sm Ternary System
  17. The Al–Si–C Phase Diagram and Its Use for Microstructural Analysis of MMCp and MMCf Composite Materials
  18. Surface Segregation and Surface Tension in Liquid Fe–Cu Alloys
  19. Mitteilungen/Notifications
  20. Personelles/Personal
  21. Bücher/Books
  22. Tagungen/Conferences
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