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High-pressure effect on grain boundary wetting in aluminium bicrystals

  • Witold Lojkowski EMAIL logo , Akira Otsuki and Andrzej Morawski
Published/Copyright: February 3, 2022
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 96 Issue 10

Abstract

The effect of pressure and misorientation on grain boundary wetting in aluminium bicrystals has been investigated. The grain boundaries were of [100] symmetrical tilt type. The wetting liquid was an Sn– Zn alloy. It is shown that the wetting angle is a function of misorientation but not of pressure. The reasons of the above results are discussed, assuming a linear dependence between the interface energy and pressure. It is shown that the difference of energy of the liquid/solid and solid/solid interface as well as the misorientation dependence of energy is simply proportional to the free volume of the interfaces.

Keywords: Pressure; Grain boundary energy; Wetting; Aluminium
Prof. Witold Lojkowski Institute for High Pressure Physics Sokolowska 29/37, 01-142 Warsaw, Poland Tel.: +48 602 758617 Fax: +48 22 5632 4218

Dedicated to Professor Dr. Lasar Shvindlerman on the occasion of his 70th birthday

References

[1] F.M. d’Heurle, O. Thomas: Defect Diff. Forum 129–130 (1996) 137.10.4028/www.scientific.net/DDF.129-130.137Search in Google Scholar

[2] B. Straumal, E.I. Rabkin, W. Lojkowski, W. Gust: Acta Mater. 45 (1997) 1931. 10.1016/S1359-6454(96)00332-1Search in Google Scholar

[3] C.A. Stickels, E.E. Hucke: Trans. Metall. Soc. AIME 230 (1964) 20. Search in Google Scholar

[4] A. Passerone, R. Sangiorgi: Acta Metall. 33 (1985) 771. 10.1016/0001-6160(85)90100-2Search in Google Scholar

[5] A. Passerone, R. Sangiorogi, N. Eustathopulos: Scripta Metall. 16 (1982) 547. 10.1016/0036-9748(82)90267-8Search in Google Scholar

[6] G. Rao, D.B. Zhang, P. Wynblatt:Acta Metall. Mater. 41 (1993) 3331. 10.1016/0956-7151(93)90062-WSearch in Google Scholar

[7] H. Miura, M. Kato, T. Mori: Colloque de Physique, Colloque C1, suppl. no.1, 51 (1990) C1-263. 10.1051/jphyscol:1990141Search in Google Scholar

[8] J.M. Howe: Interfaces in Materials, John Wiley & Sons, Inc. New York, 1997, 219. Search in Google Scholar

[9] V. Missol: Energies of Interfaces in Metals, Slask, Katowice, 1975, 32. Search in Google Scholar

[10] L.E. Murr:Interfacial Phenomena in Metals and Alloys, Addison – Wesley, London, 1975. Search in Google Scholar

[11] H. Gleiter, H. Meiser, R.W. Mirvald: Scripta metall. 14 (1980) 95. 10.1016/0036-9748(80)90133-7Search in Google Scholar

[12] A. Otsuki, H. Isono, M. Mizuno, J. de Physique: Colloque C5, suppl. au no. 10, 49 (1988) C5-563. 10.1051/jphyscol:1988569Search in Google Scholar

[13] E.I. Rabkin, W. Gust, W. Lojkowski, V. Paidar: Interface Sci. 1 (1993) 201. 10.1007/BF00198146Search in Google Scholar

[14] W. Lojkowski, E. Rabkin, B. Straumal, W. Gust:Interface Science 6 (1998) 179. 10.1023/A:1008636600201Search in Google Scholar

[15] B. Straumal, E. Rabkin, W. Lojkowski, W. Gust: Acta Mater. 45 (1997) 1931.10.1016/S1359-6454(96)00332-1Search in Google Scholar

[16] D. Wolf, K.L. Merkle, in:D. Wolf, S. Yip (Eds.), Materials Interfaces, Chapman & Hall, London, 1992, 87.Search in Google Scholar

[17 W. Lojkowski, H.J. Fecht: The structure of intercrystalline interfaces, Progress in Materials Science 45 (2000) 339.10.1016/S0079-6425(99)00008-0Search in Google Scholar
Received: 2005-05-31
Accepted: 2005-07-10
Published Online: 2022-02-03

© 2005 Carl Hanser Verlag, München

Articles in the same Issue

  1. Frontmatter
  2. Editorial
  3. Editorial
  4. Articles Basic
  5. Thermodynamics of grain boundary adsorption in binary systems with limited solubility
  6. Microstructural characteristics of 3-d networks
  7. On the three-dimensional twin-limited microstructure
  8. Grain growth kinetics in 2D polycrystals: impact of triple junctions
  9. Thermal stability of polycrystalline nanowires
  10. Conservative motion of parent-martensite interfaces
  11. Enthalpy – entropy compensation effect in grain boundary phenomena
  12. Thermodynamic stabilization of nanocrystallinity
  13. On the relation between the anisotropies of grain boundary segregation and grain boundary energy
  14. Influence of faceting-roughening on triple-junction migration in zinc
  15. The influence of triple junction kinetics on the evolution of polycrystalline materials during normal grain growth: New evidence from in-situ experiments using columnar Al foil
  16. Grain boundary dynamics and selective grain growth in non-ferromagnetic metals in high magnetic fields
  17. Grain boundary mobility under a stored-energy driving force: a comparison to curvature-driven boundary migration
  18. Diffusional behavior of nanoscale lead inclusions in crystalline aluminum
  19. Quantitative experiments on the transition between linear to non-linear segregation of Ag in Cu bicrystals studied by radiotracer grain boundary diffusion
  20. Room-temperature grain boundary diffusion data measured from historical artifacts
  21. Solid state infiltration of porous steel with aluminium by the forcefill process
  22. A mechanism of plane matching boundary-assisted α/γ phase transformation in Fe–Cr alloy based on in-situ observations
  23. Fast penetration of Ga in Al: liquid metal embrittlement near the threshold of grain boundary wetting
  24. High-pressure effect on grain boundary wetting in aluminium bicrystals
  25. Grain boundary segregation and fracture
  26. Notifications/Mitteilungen
  27. Personal/Personelles
  28. Press/Presse
  29. Conferences/Konferenzen
https://doi.org/10.1515/ijmr-2005-0208
Keywords for this article
Pressure; Grain boundary energy; Wetting; Aluminium

Articles in the same Issue

  1. Frontmatter
  2. Editorial
  3. Editorial
  4. Articles Basic
  5. Thermodynamics of grain boundary adsorption in binary systems with limited solubility
  6. Microstructural characteristics of 3-d networks
  7. On the three-dimensional twin-limited microstructure
  8. Grain growth kinetics in 2D polycrystals: impact of triple junctions
  9. Thermal stability of polycrystalline nanowires
  10. Conservative motion of parent-martensite interfaces
  11. Enthalpy – entropy compensation effect in grain boundary phenomena
  12. Thermodynamic stabilization of nanocrystallinity
  13. On the relation between the anisotropies of grain boundary segregation and grain boundary energy
  14. Influence of faceting-roughening on triple-junction migration in zinc
  15. The influence of triple junction kinetics on the evolution of polycrystalline materials during normal grain growth: New evidence from in-situ experiments using columnar Al foil
  16. Grain boundary dynamics and selective grain growth in non-ferromagnetic metals in high magnetic fields
  17. Grain boundary mobility under a stored-energy driving force: a comparison to curvature-driven boundary migration
  18. Diffusional behavior of nanoscale lead inclusions in crystalline aluminum
  19. Quantitative experiments on the transition between linear to non-linear segregation of Ag in Cu bicrystals studied by radiotracer grain boundary diffusion
  20. Room-temperature grain boundary diffusion data measured from historical artifacts
  21. Solid state infiltration of porous steel with aluminium by the forcefill process
  22. A mechanism of plane matching boundary-assisted α/γ phase transformation in Fe–Cr alloy based on in-situ observations
  23. Fast penetration of Ga in Al: liquid metal embrittlement near the threshold of grain boundary wetting
  24. High-pressure effect on grain boundary wetting in aluminium bicrystals
  25. Grain boundary segregation and fracture
  26. Notifications/Mitteilungen
  27. Personal/Personelles
  28. Press/Presse
  29. Conferences/Konferenzen
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