A curvilinear finite volume-based numerical methodology has been developed that can be effectively used for simulation of the Bridgman and Czochralski (Cz) crystal growth processes. New features of grid generation have been devised and added to the original formulation (Zhang et al., 1995, 1996) to make it suitable for global modeling. The numerical model can account for convection in both the melt and the gas phases, convection/radiation in the furnace, and conduction in all solid components. Results for Bridgman growth show that the flow pattern and interface shape strongly depend on thermal conductivities of the crystal, melt, and ampoule materials. Transient simulations have been performed for the growth of Bismuth crystal in a Bridgman-Stockbarger system and the growth of GaAs crystal using liquid-encapsulated Czochralski (LEC) technique. This is the first time that a global high-pressure LEC model is able to account for convective flows and heat transfer and predict the interface shape and its dynamics.

Issue Section:
Featured Section—Heat Transfer in Manufacturing
Keywords:
Materials Processing and Manufacturing Process, Moving Boundaries, Phase-Change Phenomena
Topics:
Crystal growth, Simulation, Crystals, Convection, Flow (Dynamics), Shapes, Computer simulation, Dynamics (Mechanics), Furnaces, Gallium arsenide, Heat conduction, Heat transfer, High pressure (Physics), Manufacturing, Materials processing, Mesh generation, Modeling, Radiation (Physics), Transients (Dynamics)
1.
Adornato
P. M.
, and
Brown
R. A.
,
1987
, “
Convection and Segregation in Directional Solidification of Dilute and Non-dilute Binary Alloys: Effects of Ampoule and Furnace Design
,”
J. Crystal Growth
, Vol.
80
, pp.
155
190
.
2.
Baumgartl
J.
,
Bune
A.
,
Koai
K.
, and
Mu¨ller
G.
,
1993
, “
Global Simulation of Heat Transport, Including Melt Convection in a Czochralski Crystal Growth Process—Combined Finite Element/Finite Volume Approach
,”
Materials Science and Engineering
, Vol.
A173
, pp.
9
13
.
3.
Brown
R. A.
,
1988
, “
Theory of Transport Processes in Single Crystal Growth from the Melt
,”
AIChE J.
, Vol.
34
, No.
6
, pp.
881
911
.
4.
Carslaw, H. S., and Jaeger, J. C., 1959, Conduction of Heat in Solids, Oxford University Press, London.
5.
Dupret, F., and van den Bogaert, N., 1994, “Modelling Bridgman and Czochralski Growth,” Handbook of Crystal Growth, Vol. 2b, D. T. J. Hurle, ed., North-Holland, New York.
6.
Dupret
F.
,
Necodeme
P.
,
Ryckmans
Y.
,
Wouters
P.
, and
Crochet
M. J.
,
1990
, “
Global Modeling of Heat and Mass Transfer in Crystal Growth Furnaces
,”
Int. J. Heat Mass Transfer
, Vol.
33
, pp.
1849
1871
.
7.
Fainberg
J.
,
Leister
H.-J.
, and
Mu¨ller
G.
,
1997
, “
Numerical Simulation of the LEC-growth of GaAs Crystals with Account of High Pressure Gas Convection
,”
J. Crystal Growth
, Vol.
180
, pp.
517
523
.
8.
Glicksman
M. E.
,
Coriell
S. R.
, and
McFadden
G. B.
,
1986
, “
Interaction of Flows with the Crystal-Melt Interface
,”
Ann. Rev. Fluid Mech.
, Vol.
18
, pp.
307
335
.
9.
Liang
M. C.
, and
Lan
C. W.
,
1996
, “
Three-dimenstional Convection and Solute Segregation in Vertical Bridgman Crystal Growth
,”
J. Crystal Growth
, Vol.
167
, pp.
320
332
.
10.
Lide, D. R., 1995, Handbook of Chemistry and Physics, 76th Ed., CRC Press, New York.
11.
Kim
D. H.
, and
Brown
R. A.
,
1991
, “
Modelling of the Dynamics of HgCdTe Growth by the Vertical Bridgman Method
,”
J. Crystal Growth
, Vol.
114
, pp.
441
434
.
12.
Kinney
T. A.
, and
Brown
R. A.
,
1993
, “
Application of Turbulence Modeling to the Integrated Hydrodynamic Thermal-Capillary Model of Czochralski Crystal Growth of Silicon
,”
J. Crystal Growth
, Vol.
132
,
551
574
.
13.
Koai
K.
,
Sonnenberg
K.
, and
Wenzl
H.
,
1994
, “
Influence of Crucible Support and Radial Heating on the Interface Shape during Vertical Bridgman GaAs Growth
,”
J. Crystal Growth
, Vol.
137
, pp.
59
63
.
14.
Maruyama
S.
, and
Aihara
T.
,
1994
, “
Radiation Heat Transfer of a Czochralski Growth Furnace with Arbitrary Specular and Diffuse Surfaces
,”
Int. J. Heat Mass Transfer
, Vol.
37
, pp.
1723
1731
.
15.
Ouyang
H.
, and
Shyy
W.
,
1996
, “
Multizone Simulation of the Bridgman Growth Process of β-NiAl Crystal
,”
Int. J. Heat Mass Transfer
, Vol.
39
, No.
10
, pp.
2039
2051
.
16.
Ramachandran
P. A.
, and
Dudukovic
M. P.
,
1985
, “
Simulation of Temperature Distribution in Crystals Grown by Czochralski Method
,”
J. Crystal Growth
, Vol.
71
, pp.
399
408
.
17.
Santailler, J. L., Duffar, T., Theodore, F., Boiton, P., Barat, C., Angelier, B., Giacommentti, N., Dusserre, P., and Nabot, J. P., 1996, “Some Features of Two Commercial Softwares for the Modeling of Bulk Crystal Growth Processes,” 2nd Int. Conf. on Modeling in Crystal Growth, Durbuy, Belguim.
18.
Tsukada
T.
,
Kakinoki
K.
,
Hozawa
M.
, and
Imaishi
N.
,
1995
, “
Effect of Internal Radiation within Crystal and Melt on Czochralski Crystal Growth of Oxide
,”
Int. J. Heat Mass Transfer
, Vol.
38
, No.
15
, pp.
2707
2714
.
19.
Zhang
H.
, and
Moallemi
M. K.
,
1995
, “
A Multizone Adaptive Grid Generation Technique for Simulation of Moving and Free Boundary Problems
,”
Num. Heat Transfer
, Vol.
B27
, pp.
255
276
.
20.
Zhang
H.
, and
Prasad
V.
,
1995
, “
A Multizone Adaptive Process Model for Crystal Growth at Low and High Pressures
,”
J. Crystal Growth
, Vol.
155
, pp.
47
65
.
21.
Zhang
H.
,
Prasad
V.
, and
Moallemi
M. K.
,
1996
, “
A Numerical Algorithm Using Multizone Adaptive Grid Generation for Multiphase Transport Processes with Moving and free Boundaries
,”
Num. Heat Transfer
, Vol.
B29
, pp.
399
421
.
22.
Zheng
L.
, and
Larson
D. J.
,
1997
, “
Thermoelectric Effects on Interface Demarcation and Directional Solidification in Bismuth
,”
J. Crystal Growth
, Vol.
180
, pp.
293
304
.
23.
Zou
Y. F.
,
Zhang
H.
, and
Prasad
V.
,
1996
, “
Dynamics of melt-crystal interface and thermal stresses in Czochralski crystal growth processes
,”
J. Crystal Growth
, Vol.
166
, pp.
476
482
.
This content is only available via PDF.
Copyright © 1998
 by The American Society of Mechanical Engineers
You do not currently have access to this content.