Solutocapillary convection in germanium‐silicon melts

Cröll, A.; Mitric, A.; Aniol, O.; Schütt, Sebastian; Simon, P.

doi:10.1002/crat.200900435

Cited by 13 publications

(5 citation statements)

References 21 publications

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“…Schwabe (2007) proposed a method to make dopants or impurities incorporate in the crystal by controlling the interaction of solutocapillarity and thermocapillarity deliberately. This feasibility has been proved by experimental investigations of solutocapillary convection (Cröll et al 2009;Arafune et al 2011;Schwabe et al 1996), numerical simulations (Abbasoglu and Sezai 2007;Minakuchi et al 2014;Lyubimova et al 2011) and linear stability analysis (Lyubimova 2007). As demonstrated experimentally by Cröll et al (2009) in a shallow rectangular crucible under microgravity, the measured velocity of the tracers is up to 55 mm/s at the onset of crystallization.…”

Section: Introductionmentioning

confidence: 86%

“…This feasibility has been proved by experimental investigations of solutocapillary convection (Cröll et al 2009;Arafune et al 2011;Schwabe et al 1996), numerical simulations (Abbasoglu and Sezai 2007;Minakuchi et al 2014;Lyubimova et al 2011) and linear stability analysis (Lyubimova 2007). As demonstrated experimentally by Cröll et al (2009) in a shallow rectangular crucible under microgravity, the measured velocity of the tracers is up to 55 mm/s at the onset of crystallization. Arafune and Hirata (1999) found that the surface velocity of solutocapillary flow is 3-5 times larger than that of the thermocapillary flow in In-Ga-Sb system in a rectangular open boat.…”

Section: Introductionmentioning

confidence: 86%

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Three-Dimensional Numerical Simulation of Pure Solutocapillary Flow in a Shallow Annular Pool for Mixture Fluid with High Schmidt Number

Chen

Zhang

et al. 2015

Microgravity Sci. Technol.

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In order to understand the characteristics of pure solutocapillary flow in a shallow annular pool subjected to a constant radial solutal gradient, a series of threedimensional numerical simulations were performed. The annular pool was filled with the toluene/n-hexane mixture fluid with the Schmidt number of 142.8. The inner and outer cylinders were respectively maintained at low and high solutal concentrations. Aspect ratio of the annular pool is fixed at ε = 0.15 or 0.05. Results indicate that the solutocapillary flow is steady and axisymmetric at a small solutal capillary Reynolds number. The surface fluid flows radially from the inner cylinder toward the outer cylinder and a return flow exists near the bottom. With the increase of the solutal capillary Reynolds number, an axisymmetric oscillatory flow firstly appears and then becomes a three-dimensional oscillatory flow at ε = 0.15. Whereas at ε = 0.05, a direct transition from the steady and axisymmetric flow to the three-dimensional oscillatory flow is observed. Three types of the flow instabilities are the standing wave, hydrosolutal wave and source/sink type wave instabilities. Furthermore, the physical mechanism of the flow destabilization is analyzed. NomenclatureC mass fraction of solutal d depth, m D mass diffusivity of species, m 2 /s F dimensionless frequency m wave number P dimensionless pressure r radius, m R dimensionless radius Re solutocapillary Reynolds number Sc Schmidt number, Sc = ν/D T temperature, • C v velocity, m/s V dimensionless velocity vector z axial coordinate, m Z dimensionless axial coordinate Greek symbols ε aspect ratio, d/(r ocoefficient of surface tension, N/m η radius ratio, r i /r o μ dynamic viscosity, kg/(m·s) ν kinematic viscosity, m 2 /s θ azimuthal coordinate, rad ρ density, kg/m 3 σ surface tension, N/m τ dimensionless time ψ dimensionless stream function Subscripts 0 Initial c Critical i inner wall o outer wall 50 Microgravity Sci. Technol. (2016) 28:49-57 p P e r i o d R, Z, θ coordinate directions

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Section: Introductionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 86%

Three-Dimensional Numerical Simulation of Pure Solutocapillary Flow in a Shallow Annular Pool for Mixture Fluid with High Schmidt Number

Chen

Zhang

et al. 2015

Microgravity Sci. Technol.

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“…According to Cröll et al [86], such mixed convection is explained below. According to Cröll et al [86], such mixed convection is explained below.…”

Section: Bridgman Edge-defined Film-fed and Othermentioning

confidence: 96%

“…Cröll et al [86] carried out the directional solidification experiments of Ge x Si 1Àx mixtures of different compositions between 3% and 9% Si under microgravity condition during a parabolic flight campaign, where the samples of 2-3 mm in depth poured in a SiC-coated graphite crucible (inside dimensions 15 Â 30 mm 2 ) were heated by a doubleellipsoid mirror furnace whose two lamps were focused onto one end of the crucible. Figure 22.29 shows the three different experimental stages with a schematic view of the convective flow and the position of tracers put to visualize the flow direction of the solutocapillary flows: (a) the sample is completely melted by equally heating from both sides, and the cold spot is in the crucible center leading to two opposing thermocapillary convective rolls, (b) completely molten sample is reduced heating from the right side, and consequently the cold spot moves near the crucible wall, leading to a much reduced thermocapillary convective roll on the right, and (c) solidification starts from the right side, and solutocapillary flow caused by the concentration gradient along the surface due to segregation pushes the tracers away from the melt/crystal interface, where solutocapillary convection opposes thermocapillary convection in the Ge x Si 1-x system since Si, having the higher surface tension, is preferentially incorporated into the crystal during growth.…”

Section: Bridgman Edge-defined Film-fed and Othermentioning

confidence: 99%

The Role of Marangoni Convection in Crystal Growth

Tsukada

2015

Handbook of Crystal Growth

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“…For the compound semiconductor crystal growth, the coupling thermal and solutocapillarybuoyancy effects in the mixture are rather more complex than that of pure fluid. Cröll et al [38] conducted an experiment during the parabolic flight campaign to separate the buoyancy effect from the capillary convection. The solutocapillary convection was conclusively observed during the solidification of silicon-germanium.…”

Section: Introductionmentioning

confidence: 99%

Mixed Oscillation Flow of Binary Fluid with Minus One Capillary Ratio in the Czochralski Crystal Growth Model

Chen

2020

Crystals

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This work presented a series of three-dimensional unsteady numerical simulations on the characteristics of the mixed oscillation flows of binary mixture in a Czochralski crystal growth model. The silicon-germanium melt is investigated and the capillary ratio is minus one. The simulation results showed that, for the special capillary ratio, the thermal and solutocapillary forces are imposed in opposite directions and counteract each other. With the effect of buoyancy, the balance between the capillary forces is disturbed. Mixed with the forced convection driven by rotation, the capillary-buoyancy convection is complex. The basic mixed flow streamlines are presented as various rolling cells. The directions of the rolls are dependent on the combinations of surface and body forces. With the increase of temperature gradient, the basic flow stability is broken, and the oscillations occur. The crucible rotation has an effective influence on the stability enhancement. However, affected by the crystal rotation, the critical condition experiences an increase to a turning point, and then undergoes a sharp reduction to zero. Once the instability is incubated, the surface oscillations are analyzed. For the three-dimensional steady flow, only spatial oscillations are observed circumferentially, and the surface patterns of spokes, rosebud, and pulsating ring are obtained. For the unsteady oscillation flow, the spiral hydrosoultal waves, rotating waves, and superimposition of spirals and spokes are observed, and the oscillation behaviors are also discussed.

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Solutocapillary convection in germanium‐silicon melts

Cited by 13 publications

References 21 publications

Three-Dimensional Numerical Simulation of Pure Solutocapillary Flow in a Shallow Annular Pool for Mixture Fluid with High Schmidt Number

Three-Dimensional Numerical Simulation of Pure Solutocapillary Flow in a Shallow Annular Pool for Mixture Fluid with High Schmidt Number

The Role of Marangoni Convection in Crystal Growth

Mixed Oscillation Flow of Binary Fluid with Minus One Capillary Ratio in the Czochralski Crystal Growth Model

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