Interface shape, heat transfer and fluid flow in the floating zone growth of large silicon crystals with the needle-eye technique

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Alfred Mühlbauer
  • Andris Muiznieks
  • Janis Virbulis
  • Anke Lüdge
  • Helge Riemann

Organisationseinheiten

Externe Organisationen

  • Leibniz-Institut für Kristallzüchtung (IKZ)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)66-79
Seitenumfang14
FachzeitschriftJournal of crystal growth
Jahrgang151
Ausgabenummer1-2
PublikationsstatusVeröffentlicht - 2 Mai 1995

Abstract

A computer simulation is carried out to study the interface shape, heat transfer and fluid flow in the floating zone (FZ) growth of large (> 100 mm) Si crystals with the needle-eye technique and with feed/crystal rotation. Natural convection, thermocapillary convection, electromagnetic (EM) forces and rotation in the melt are considered. The unknown shape of the molten zone is calculated as a coupled thermal-electromagnetic-hydrodynamic problem and compared with that observed during experiments. The effects of the growth rate and the process stage on the shape of the interface are demonstrated. It was observed that natural convection and rotation dominate over thermocapillary and EM convection, at least for conditions corresponding to the industrial FZ Si production with the needle-eye technique. It is shown that under these conditions the rotation destabilizes the flow and only unsteady flows exist in the molten zone. The calculated distributions of the oscillation amplitude of the tangential velocity at the growing interface correspond to the radial resistivity distributions measured in the single crystal by the photo-scanning method.

ASJC Scopus Sachgebiete

Zitieren

Interface shape, heat transfer and fluid flow in the floating zone growth of large silicon crystals with the needle-eye technique. / Mühlbauer, Alfred; Muiznieks, Andris; Virbulis, Janis et al.
in: Journal of crystal growth, Jahrgang 151, Nr. 1-2, 02.05.1995, S. 66-79.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Mühlbauer A, Muiznieks A, Virbulis J, Lüdge A, Riemann H. Interface shape, heat transfer and fluid flow in the floating zone growth of large silicon crystals with the needle-eye technique. Journal of crystal growth. 1995 Mai 2;151(1-2):66-79. doi: 10.1016/0022-0248(95)00027-5
Mühlbauer, Alfred ; Muiznieks, Andris ; Virbulis, Janis et al. / Interface shape, heat transfer and fluid flow in the floating zone growth of large silicon crystals with the needle-eye technique. in: Journal of crystal growth. 1995 ; Jahrgang 151, Nr. 1-2. S. 66-79.
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abstract = "A computer simulation is carried out to study the interface shape, heat transfer and fluid flow in the floating zone (FZ) growth of large (> 100 mm) Si crystals with the needle-eye technique and with feed/crystal rotation. Natural convection, thermocapillary convection, electromagnetic (EM) forces and rotation in the melt are considered. The unknown shape of the molten zone is calculated as a coupled thermal-electromagnetic-hydrodynamic problem and compared with that observed during experiments. The effects of the growth rate and the process stage on the shape of the interface are demonstrated. It was observed that natural convection and rotation dominate over thermocapillary and EM convection, at least for conditions corresponding to the industrial FZ Si production with the needle-eye technique. It is shown that under these conditions the rotation destabilizes the flow and only unsteady flows exist in the molten zone. The calculated distributions of the oscillation amplitude of the tangential velocity at the growing interface correspond to the radial resistivity distributions measured in the single crystal by the photo-scanning method.",
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AU - Mühlbauer, Alfred

AU - Muiznieks, Andris

AU - Virbulis, Janis

AU - Lüdge, Anke

AU - Riemann, Helge

N1 - Funding Information: The authors are grateful for the support of Federal Ministry for Research and Technology (Germany) Project 01M2930. Copyright: Copyright 2015 Elsevier B.V., All rights reserved.

PY - 1995/5/2

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N2 - A computer simulation is carried out to study the interface shape, heat transfer and fluid flow in the floating zone (FZ) growth of large (> 100 mm) Si crystals with the needle-eye technique and with feed/crystal rotation. Natural convection, thermocapillary convection, electromagnetic (EM) forces and rotation in the melt are considered. The unknown shape of the molten zone is calculated as a coupled thermal-electromagnetic-hydrodynamic problem and compared with that observed during experiments. The effects of the growth rate and the process stage on the shape of the interface are demonstrated. It was observed that natural convection and rotation dominate over thermocapillary and EM convection, at least for conditions corresponding to the industrial FZ Si production with the needle-eye technique. It is shown that under these conditions the rotation destabilizes the flow and only unsteady flows exist in the molten zone. The calculated distributions of the oscillation amplitude of the tangential velocity at the growing interface correspond to the radial resistivity distributions measured in the single crystal by the photo-scanning method.

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