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crystallography (554) 554
directional solidification (482) 482
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materials science, multidisciplinary (416) 416
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multikristallines silicium (48) 48
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microstructure (45) 45
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stability (41) 41
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computer-generated environments (39) 39
crystal morphology (37) 37
crystal structure (36) 36
heat transfer (36) 36
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defects (35) 35
diffusion (34) 34
morphological stability (34) 34
tiegel (34) 34
erstarren (33) 33
numerische simulation (33) 33
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temperaturgradient (32) 32
crucibles (31) 31
flow (30) 30
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magnetisches feld (30) 30
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crystallization (28) 28
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chemical sciences (27) 27
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polycrystalline silicon (25) 25
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carbon (24) 24
fluide strömung (24) 24
multi-crystalline silicon (24) 24
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bridgman method (23) 23
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microgravity (22) 22
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single crystal growth (22) 22
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Journal of crystal growth, ISSN 0022-0248, 2013, Volume 377, pp. 192 - 196
Journal Article
Journal of crystal growth, ISSN 0022-0248, 2016, Volume 439, pp. 40 - 46
The evolution of grain structures, especially the types of grain boundaries (GBs), during directional solidification is crucial to the electrical properties of multicrystalline silicon used for solar cells... 
A1. Solidification | A1. Nucleation | A1. Planar defects | B2. Semiconducting silicon | PHYSICS, APPLIED | Nucleation | SOLAR-CELLS | MELT | ZONE | MATERIALS SCIENCE, MULTIDISCIPLINARY | POLYCRYSTALLINE SILICON | ORIENTATIONS | CRYSTALLOGRAPHY | Planar defects | MULTI-CRYSTALLINE SILICON | Solidification | GROWTH | STRING RIBBON | Semiconducting silicon | Grain boundaries | Silicon | Semiconductor wafers | Directional solidification | Grains | Wafers | Evolution | Drift | Orientation | Grain structure
Journal Article
Journal of Crystal Growth, ISSN 0022-0248, 02/2019, Volume 508, pp. 42 - 49
....•Preferred twinning sites in the previous experiments are predicted. Heterogeneous twinning nucleation from the wall or gas interface during directional solidification... 
A1. Heterogeneous | B2. Silicon | A1. Facets | A1. Nucleation | A1. Twinning | A1. Undercooling | GRAIN-BOUNDARIES | PHYSICS, APPLIED | Nucleation | Facets | MECHANISM | MATERIALS SCIENCE, MULTIDISCIPLINARY | Twinning | CRYSTALLOGRAPHY | FACET | Heterogeneous | EVOLUTION | GROWTH | Undercooling | Silicon | X ray imagery | Directional solidification | Material chemistry | Chemical Sciences
Journal Article
Journal of crystal growth, ISSN 0022-0248, 2018, Volume 492, pp. 18 - 23
Journal Article
Journal of Crystal Growth, ISSN 0022-0248, 03/2014, Volume 389, pp. 47 - 54
Journal Article
Journal of Crystal Growth, ISSN 0022-0248, 02/2014, Volume 387, pp. 10 - 15
Development of grain structures of multi-crystalline silicon from small spherical seeds with random orientations in directional solidification was investigated... 
B2. Silicon | A3. Grain growth | A3. Twin boundaries | A1. Directional solidification | PHYSICS, APPLIED | SOLAR-CELLS | Directional solidification | Grain growth | MELT | MATERIALS SCIENCE, MULTIDISCIPLINARY | POLYCRYSTALLINE SILICON | CRYSTALLOGRAPHY | Twin boundaries | SIGE | COMPETITION | TWINNING OCCURRENCE | GROWTH-BEHAVIOR | Silicon | IN-SITU OBSERVATIONS | Analysis | Seeds
Journal Article
Journal of Crystal Growth, ISSN 0022-0248, 12/2012, Volume 360, Issue 1, pp. 99 - 104
Journal Article
Journal of crystal growth, ISSN 0022-0248, 2017, Volume 457, pp. 270 - 274
.... •Resolving TEMHD in interdendritic region in directional solidification.•Computational model of macrosegregation through TEMHD mass transport.•Favourable comparison to experimental results. 
A1. Mass transfer | A1. Magnetic fields | A1. Directional solidification | A. Thermoelectric currents | A1. Crystal structure | PHYSICS, APPLIED | Directional solidification | CONVECTION | MATERIALS SCIENCE, MULTIDISCIPLINARY | Thermoelectric currents | CRYSTALLOGRAPHY | Magnetic fields | Mass transfer | MORPHOLOGY | Crystal structure | AL-CU ALLOYS | INTERFACE SHAPE | Fluid dynamics | Numerical analysis
Journal Article
Journal of crystal growth, ISSN 0022-0248, 2019, Volume 522, pp. 183 - 190
....•The remelting and coarsening of sidebranch are analysed. In this paper, the phase field method is used to study the multi control factors during directional solidification sidebranching growth of Al-Si alloy... 
A1. Computer simulation | B1. Alloys | A2. Growth from melt | A1. Defects | GRAINS | PHYSICS, APPLIED | Computer simulation | MATERIALS SCIENCE, MULTIDISCIPLINARY | Alloys | GROWTH COMPETITION | CRYSTALLOGRAPHY | Growth from melt | MODEL | Defects | Analysis | Aluminum base alloys | Melting | Directional solidification | Morphology | Temperature gradients | Thermal noise | Dendritic structure | Coarsening
Journal Article
Journal of Crystal Growth, ISSN 0022-0248, 01/2019, Volume 506, pp. 97 - 101
.... We investigate how macrosegregation formation during directional solidification can be purposefully influenced to form sequences of concentration gradients along rod shaped samples... 
A1. Concentration gradient | A1. Directional solidification | B1. Alloys | A1. Convection | B1. Graded material | A1. Diffusion | PHYSICS, APPLIED | Directional solidification | MELT | ZONE | MATERIALS SCIENCE, MULTIDISCIPLINARY | Alloys | CRYSTALLOGRAPHY | DILUTE | Convection | Graded material | RESOLIDIFICATION | TEMPERATURE-GRADIENT | Diffusion | MULTICOMPONENT ALLOYS | Concentration gradient | PLANAR INTERFACE
Journal Article