Convectional controlled crystal-melt interface using two-phase radio-frequency electromagnetic heating

R. Hermann; G. Gerbeth; J. Priede; A. Krauze; G. Behr; B. Büchner

doi:10.1007/s10853-009-4117-0

Convectional controlled crystal-melt interface using two-phase radio-frequency electromagnetic heating

R. Hermann^*
, G. Gerbeth
, J. Priede
, A. Krauze
, G. Behr
, B. Büchner

^*Corresponding author for this work

Institute of Numerical Modeling

Leibniz Institute for Solid State and Materials Research Dresden
Helmholtz-Zentrum Dresden-Rossendorf
Coventry University

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

The radio frequency floating-zone growth of massive intermetallic single crystals is very often unsuccessful due to an unfavourable solid-liquid interface geometry enclosing concave fringes. This interface depends on the flow in the molten zone. A tailored magnetic two-phase stirrer system has been developed which enables the controlled influence on the melt flow ranging from intense inwards to outwards flows. Depending on the phase shift between the two induction coils, a transition from a double vortex structure to a single vortex structure is created at a preferable phase shift of 90°. This change in the flow field has a significant influence on the shape of the solid-liquid interface. Due to their attractive properties for high temperature applications such as high melting temperature, low density, high modulus and good oxidation resistance, the magnetic system was applied to the crystal growth of TiAl alloys.

Original language	English
Pages (from-to)	2228-2232
Number of pages	5
Journal	Journal of Materials Science
Volume	45
Issue number	8
DOIs	https://doi.org/10.1007/s10853-009-4117-0
Publication status	Published - Apr 2010

OECD Field of Science

1.3 Physical Sciences

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10.1007/s10853-009-4117-0

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title = "Convectional controlled crystal-melt interface using two-phase radio-frequency electromagnetic heating",

abstract = "The radio frequency floating-zone growth of massive intermetallic single crystals is very often unsuccessful due to an unfavourable solid-liquid interface geometry enclosing concave fringes. This interface depends on the flow in the molten zone. A tailored magnetic two-phase stirrer system has been developed which enables the controlled influence on the melt flow ranging from intense inwards to outwards flows. Depending on the phase shift between the two induction coils, a transition from a double vortex structure to a single vortex structure is created at a preferable phase shift of 90°. This change in the flow field has a significant influence on the shape of the solid-liquid interface. Due to their attractive properties for high temperature applications such as high melting temperature, low density, high modulus and good oxidation resistance, the magnetic system was applied to the crystal growth of TiAl alloys.",

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T1 - Convectional controlled crystal-melt interface using two-phase radio-frequency electromagnetic heating

AU - Hermann, R.

AU - Gerbeth, G.

AU - Priede, J.

AU - Krauze, A.

AU - Behr, G.

AU - Büchner, B.

PY - 2010/4

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N2 - The radio frequency floating-zone growth of massive intermetallic single crystals is very often unsuccessful due to an unfavourable solid-liquid interface geometry enclosing concave fringes. This interface depends on the flow in the molten zone. A tailored magnetic two-phase stirrer system has been developed which enables the controlled influence on the melt flow ranging from intense inwards to outwards flows. Depending on the phase shift between the two induction coils, a transition from a double vortex structure to a single vortex structure is created at a preferable phase shift of 90°. This change in the flow field has a significant influence on the shape of the solid-liquid interface. Due to their attractive properties for high temperature applications such as high melting temperature, low density, high modulus and good oxidation resistance, the magnetic system was applied to the crystal growth of TiAl alloys.

AB - The radio frequency floating-zone growth of massive intermetallic single crystals is very often unsuccessful due to an unfavourable solid-liquid interface geometry enclosing concave fringes. This interface depends on the flow in the molten zone. A tailored magnetic two-phase stirrer system has been developed which enables the controlled influence on the melt flow ranging from intense inwards to outwards flows. Depending on the phase shift between the two induction coils, a transition from a double vortex structure to a single vortex structure is created at a preferable phase shift of 90°. This change in the flow field has a significant influence on the shape of the solid-liquid interface. Due to their attractive properties for high temperature applications such as high melting temperature, low density, high modulus and good oxidation resistance, the magnetic system was applied to the crystal growth of TiAl alloys.

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Convectional controlled crystal-melt interface using two-phase radio-frequency electromagnetic heating

Abstract

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