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Thermodynamic assessment of the Ca–Sn system

  • Y. Cartigny EMAIL logo , J. M. Fiorani , A. Maître and M. Vilasi
Published/Copyright: February 4, 2022
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 96 Issue 11

Abstract

Thermodynamic modelling of the Ca–Sn binary system was carried out. The thermodynamic parameters related to this system were determined from experimental phase diagram and thermodynamic information available in the literature. In this system the liquid phase was modelled by the association model with the “Ca2Sn” associated complex. This consideration permits to well restore experimental values. A set of thermodynamic interaction parameters, the calculated phase diagram as well as the comparison with experimental data are presented.

Keywords: Calcium-tin system; Thermodynamic modelling; Association model
Yohann Cartigny Laboratoire de Chimie du Solide Minéral – UMR 7555 Université Henri, Poincaré Nancy 1 Boulevard des aiguillettes – BP 239 F-54506 Vandoeuvre les Nancy Cedex, France Tel.: +33 3 83 68 46 55 Fax: +33 3 83 68 46 50

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Received: 2004-08-16
Accepted: 2005-02-20
Published Online: 2022-02-04

© 2005 Carl Hanser Verlag, München

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https://doi.org/10.1515/ijmr-2005-0228
Keywords for this article
Calcium-tin system; Thermodynamic modelling; Association model

Articles in the same Issue

  1. Frontmatter
  2. Editorial
  3. nanomech 5
  4. Articles Basic
  5. Quantitative evaluation of nanoindents: Do we need more reliable mechanical parameters for the characterization of materials?
  6. Nanoindentation investigation of solid-solution strengthening in III-V semiconductor alloys
  7. Comparison between conventional Vickers hardness and indentation hardness obtained with different instruments
  8. On the pressure dependence of the indentation modulus
  9. A review on the reverse analysis for the extraction of mechanical properties using instrumented Vickers indentation
  10. Articles Applied
  11. Quasi-static and dynamic depth-sensing indentation measurements to characterize wear and mar resistance of coating–polymer systems
  12. Obtaining mechanical parameters for metallisation stress sensor design using nanoindentation
  13. Direct measurement of nanoindentation area function by metrological AFM
  14. A usable concept for the indentation of thin porous films
  15. Analysis of the ductile/brittle transition during a scratch test performed into polymeric film deposited on a PMMA substrate
  16. Nanomechanical and nanotribological properties of polymeric ultrathin films for nanoimprint lithography
  17. Adhesive and nanomechanical properties of polymeric films deposited on silicon
  18. Modelling of the nanoindentation process of ultrathin films
  19. Regular articles
  20. Experimental investigation and thermodynamic calculation in the Al–Be–Si ternary system
  21. Thermodynamic assessment of the Ca–Sn system
  22. Interfacial reaction between Cu and Ti2SnC during processing of Cu–Ti2SnC composite
  23. Effects of heat treatment on the lubricated sliding wear behaviour of zinc-based alloy containing nickel under varying test conditions
  24. Influence of Ce, K, and Na on spheroidization of eutectic carbides in low-tungsten white cast iron
  25. Notifications/Mitteilungen
  26. Personal/Personelles
  27. Press/Presse
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