Your search keyword '"K.W. Benz"' showing total 3 results

1. Rotating magnetic fields: Fluid flow and crystal growth applications

Author

P. Dold and K.W. Benz

Subjects

Convection, Zone melting, Natural convection, business.industry, Chemistry, Taylor–Couette flow, Field strength, Mechanics, Condensed Matter Physics, Forced convection, Magnetic field, Flow control (fluid), Optics, General Materials Science, business

Abstract

Rotating or alternating magnetic fields are widely used in the industrial steel casting process or in metallurgical manufacturing. For the growth of single crystals, these techniques attracted a rapidly increasing attention within the last years: a well defined melt flow leads to a more homogeneous temperature and concentration distribution in the melt and consequently improves the growth process. Rotating magnetic fields (RMF) might be used instead of crucible and/or crystal rotation avoiding mechanically induced disturbances or might be added to conventional rotation mechanisms to gain a further flow control parameter. Compared to static magnetic fields, rotating ones are distinguished by a much lower energy consumption and technical effort. Furthermore, there are no reports on detrimental effects such as the generation of thermoelectromagnetic convection or coring effects in the grown crystals. One advantage of rotating magnetic fields is the possibility to apply them even to melts with a rather low electrical conductivity like e.g. aqueous solutions. High flow velocities are already generated with moderate fields. Therefore the field strength has to be adjusted with care because otherwise undesirable Taylor vortices might be induced. In the last years, the potential of rotating magnetic fields for crystal growth processes was demonstrated for model arrangements using e.g. gallium or mercury as a test liquid as well as for a variety of growth techniques like Float Zone, Czochralski, Bridgman, or Travelling Heater Methods: Fluctuations of the heat transport due to time-dependent natural convection have could be reduced by more than an order of magnitude or the mass transport could be improved with respect to the a better radial symmetry and/or a more homogeneous microscopic segregation.

Published

1999

2. Static magnetic fields in semiconductor floating-zone growth

Author

A. Cröll and K.W. Benz

Subjects

Convection, Zone melting, Marangoni effect, Dopant, Condensed matter physics, Chemistry, business.industry, Condensed Matter Physics, Magnetic field, Forced convection, Optics, Magnetic damping, General Materials Science, business, Striation

Abstract

Heat and mass transfer in semiconductor float-zone processing are strongly influenced by convective flows in the zone, originating from sources such as buoyancy convection, thermocapillary (Marangoni) convection, differential rotation, or radio frequency heating. Because semiconductor melts are conducting, flows can be damped by the use of static magnetic fields to influence the interface shape and the segregation of dopants and impurities. An important objective is often the suppression of time-dependent flows and the ensuing dopant striations. In RF-heated Si-FZ - crystals, fields up to O.STesla show some flattening of the interface curvature and a reduction of striation amplitudes. In radiation-heated (small-scale) SI-FZ crystals, fields of 0.2 - 0.5 Tesla already suppress the majority of the dopant striations. The uniformity of the radial segregation is often compromised by using a magnetic field, due to the directional nature of the damping. Transverse fields lead to an asymmetric interface shape and thus require crystal rotation (resulting in rotational dopant striations) to achieve a radially symmetric interface, whereas axial fields introduce a coring effect. A complete suppression of dopant striations and a reduction of the coring to insignificant values, combined with a shift of the axial segregation profile towards a more diffusion-limited case, are possible with axial static fields in excess of 1 Tesla. Strong static magnetic fields, however, can also lead to the appearance of thermoelectromagnetic convection, caused by the interaction of thermoelectric currents with the magnetic field.

Published

1999

3. Crystal growth under reduced gravity

Author

K.W. Benz

Subjects

Reduced Gravity, Silicon, business.industry, Analytical chemistry, chemistry.chemical_element, Mineralogy, Crystal growth, Condensed Matter Physics, Cadmium telluride photovoltaics, Ampoule, Metal, Semiconductor, chemistry, visual_art, visual_art.visual_art_medium, General Materials Science, business, Quartz

Abstract

During the German Spacelab mission D1 various Crystal Growth Experiments have been successfully performed. The aim of this article is to review those growth studies which have been carried out in ellipsoidal mirror furnace systems. A Floating Zone Technique has been applied to Si whereas GaSb, InP, CdTe and (Pb, Sn) Te have been grown in quartz ampoules by the Travelling Heater Method (THM). One CdTe-growth run used a vapour zone instead of a metallic solution zone. As a main result of all experiments it could be demonstrated that semiconductor crystals may be grown under reduced gravity conditions in a nearly diffusive growth regime.

Published

1993