Publication:
Three-dimensional simulation of flow and thermal field in a Czochralski melt using a block-structured finite-volume method

cris.customurl9181
cris.virtual.departmentStrömungsmechanik
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cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
cris.virtual.departmentbrowseStrömungsmechanik
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cris.virtualsource.departmentba61e71a-d073-4609-89b6-c10b460b09a8
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dc.contributor.authorBasu, Biswajit
dc.contributor.authorEnger, Sven
dc.contributor.authorBreuer, Michael
dc.contributor.authorDurst, Franz
dc.date.issued2000
dc.description.abstractThe three-dimensional and time-dependent turbulent flow field and heat transfer of the melt in a Czochralski crystal growth process were predicted using an efficient block-structured finite-volume Navier-Stokes solver. The present paper is a first step towards adopting a block-structured finite-volume method for simulating turbulent flow in a Czochralski melt. Different ways of creating high-quality block-structured grids for the crucible are described along with their advantages over structured grids. In order to study the cellular convection pattern in an industrial Czochralski melt, three-dimensional simulations of turbulent flow and thermal field were carried out on two grid levels in five blocks. Using a special form of discretization of the convective fluxes, the flow field was predicted without applying any turbulence model. The accuracy of the discretization of the convective terms and size of control volumes were shown to affect greatly the characteristics of the flow field. With fine grids, the predicted thermal field was seen to be in close agreement with the reported experimental observation and numerical prediction of melt surface thermal field as well as temperature fluctuations. The flow field was shown to transform through a number of intermediate stages such as spoke pattern, n-folded pattern with island, etc., until a stable cellular flow field is established with weak co-rotating waves at the surface. The mechanism of these waves is baroclinic instability. © 2000 Elsevier Science B.V. All rights reserved.
dc.description.versionNA
dc.identifier.citationIn: Journal of crystal growth. - Amsterdam [u.a.] : Elsevier, ISSN 0022-0248, ZDB-ID 3043-0 - Bd. 219.2000, 1, S. 123-143, insges. 21 S.
dc.identifier.doi10.1016/S0022-0248(00)00591-1
dc.identifier.issn0022-0248
dc.identifier.scopus2-s2.0-0001182168
dc.identifier.urihttps://openhsu.ub.hsu-hh.de/handle/10.24405/9181
dc.language.isoen
dc.publisherElsevier
dc.relation.journalJournal of Crystal Growth
dc.relation.orgunitUniversität Erlangen-Nürnberg
dc.rights.accessRightsmetadata only access
dc.titleThree-dimensional simulation of flow and thermal field in a Czochralski melt using a block-structured finite-volume method
dc.typeResearch article
dcterms.bibliographicCitation.originalpublisherplaceAmsterdam
dspace.entity.typePublication
hsu.uniBibliographyNein
oaire.citation.endPage143
oaire.citation.issue1
oaire.citation.startPage123
oaire.citation.volume219
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