Numerical study of thermal stress during different stages of silicon Czochralski crystal growth
In this paper, the influence of various crystal heights to the crystal/melt
interface shape and thermal stresses distribution in the large diameter (300 mm) of the
silicon single crystal growth in a Czochralski process was studied numerically. A tow
dimensional fluid flow and heat transfer with solidification model was developed. The
Navier-Stoks and energy equations in melt and the heat conduction equation in crystal
are solved using the control volume-based finite difference method. The thermal elastic
stress fields for different stages are calculated from the temperature field by adopting the
plane strain model in an axi-symmetric geometry of a cylindrical crystal. It was found
that the melt/crystal interface shape becomes more concave and the maximum value of
thermal stress in the crystal reduces as the crystal grows. A good agreement between our
numerical simulations and those found in the literature is obtained.
Document joint
Mots-clés
- Crystal
- Crystal/melt interface shape
- Czochralski
- Silicon
-
Solidification
-
- Study of storage thermal energy of latent heat Application to the solar collector
- Influence De La Vitesse De Solidification Et De Refroidissement Sur La Microstructure Et Les Propriétés Mécaniques De La Fonte FGL200 Lors De L’utilisation De Différents Matériaux De Remplissage En Moulage A Masque
- Thermal stress
fr
Science et Technologie
Revue des Energies Renouvelables
volume 12
Numéro 04
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