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Systems with free melt surfaces are frequently affected by gravity independent, capillary flows due to the tempera- ture and /or concentration dependence of the surface tension.For low Prandtl number liquids like metal or semicon- ductor melts, small temperature differences are already suffi cient to cause a time-dependent flow regime, which in- duces fluctuation of the temperature and the velocity field of the melt. The high electrical conductivity of the low Prandtl number substances makes the use of magnetic fields the first choice for flow control and the elimination of undesirable flow structures. Static magnetic fields or dynamic ones are in use. In radiation-heated float zones, the time-dependent natural convection results in irregular temperature fluctuations in the melt, which reach peak-to-peak values of 1 K; their frequency range is between 0.05 and 0.2 Hz. Numerical simulations reveal flow velocities in the range of 15 cm /s.Static axial magnetic fields result in crystals free of (detectable) microsegregation. The radial dopant distribution is distorted by the magnetic field due to the establishment of stationary flow cells. Static magnetic fields can induce thermoelectromagnetic flows ahead of the solid-liquid inter- face, which cause strong compositional irregularities in the µm to mm range.Applying rotating magnetic fields, the convectively induced temperature fluctuations can be reduced by more than one order of magnitude.The microsegregation is nearly eliminated and the radial dopant distribution is improved.
収録刊行物
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- 日本マイクログラビティ応用学会誌
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日本マイクログラビティ応用学会誌 20 (3), 175-, 2003-07-31
日本マイクログラビティ応用学会
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詳細情報 詳細情報について
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- CRID
- 1391694356260728320
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- NII論文ID
- 130007971874
- 10011716055
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- NII書誌ID
- AN10537663
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- NDL書誌ID
- 6659502
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- ISSN
- 09153616
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- 本文言語コード
- en
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- データソース種別
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- JaLC
- NDL
- CiNii Articles
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