The use of magnetic fields in vertical Bridgman/Gradient Freeze-type crystal growth

Olf Pätzold; Kathrin Niemietz; Ronny Lantzsch; Vladimir Galindo; Ilmars Grants; Martin Bellmann; Gunter Gerbeth

doi:10.1140/epjst/e2013-01811-6

The use of magnetic fields in vertical Bridgman/Gradient Freeze-type crystal growth

Olf Pätzold^*
, Kathrin Niemietz
, Ronny Lantzsch
, Vladimir Galindo
, Ilmars Grants
, Martin Bellmann
, Gunter Gerbeth

^*Šī darba korespondējošais autors

Freiberg University of Mining and Technology
Hanwha Q Cells GmbH
Helmholtz-Zentrum Dresden-Rossendorf
Norwegian University of Science and Technology

Zinātniskās darbības rezultāts: Devums žurnālam › Pārskata raksts › koleģiāli recenzēts

16 Atsauces (Scopus)

Kopsavilkums

This paper outlines advanced vertical Bridgman/Gradient Freeze techniques with flow control using magnetic fields developed for the growth of semiconductor crystals. Low-temperature flow modelling, as well as laboratory-scaled crystal growth under the influence of rotating, travelling, and static magnetic fields are presented. Experimental and numerical flow modelling demonstrate the potential of the magnetic fields to establish a well-defined flow for tailoring heat and mass transfer in the melt during growth. The results of the growth experiments are discussed with a focus on the influence of a rotating field on the segregation of dopants, the influence of a travelling field on the temperature field and thermal stresses, and the potential of rotating and static fields for a stabilization of the melt flow.

Oriģinālvaloda	Angļu
Lapas (no-līdz)	243-257
Lapu skaits	15
Žurnāls	European Physical Journal: Special Topics
Sējums	220
Izdevuma numurs	1
DOIs	https://doi.org/10.1140/epjst/e2013-01811-6
Publikācijas statuss	Publicēts - 2013
Ārēji publicēts	Jā

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abstract = "This paper outlines advanced vertical Bridgman/Gradient Freeze techniques with flow control using magnetic fields developed for the growth of semiconductor crystals. Low-temperature flow modelling, as well as laboratory-scaled crystal growth under the influence of rotating, travelling, and static magnetic fields are presented. Experimental and numerical flow modelling demonstrate the potential of the magnetic fields to establish a well-defined flow for tailoring heat and mass transfer in the melt during growth. The results of the growth experiments are discussed with a focus on the influence of a rotating field on the segregation of dopants, the influence of a travelling field on the temperature field and thermal stresses, and the potential of rotating and static fields for a stabilization of the melt flow.",

author = "Olf P{\"a}tzold and Kathrin Niemietz and Ronny Lantzsch and Vladimir Galindo and Ilmars Grants and Martin Bellmann and Gunter Gerbeth",

year = "2013",

doi = "10.1140/epjst/e2013-01811-6",

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T1 - The use of magnetic fields in vertical Bridgman/Gradient Freeze-type crystal growth

AU - Pätzold, Olf

AU - Niemietz, Kathrin

AU - Lantzsch, Ronny

AU - Galindo, Vladimir

AU - Grants, Ilmars

AU - Bellmann, Martin

AU - Gerbeth, Gunter

PY - 2013

Y1 - 2013

N2 - This paper outlines advanced vertical Bridgman/Gradient Freeze techniques with flow control using magnetic fields developed for the growth of semiconductor crystals. Low-temperature flow modelling, as well as laboratory-scaled crystal growth under the influence of rotating, travelling, and static magnetic fields are presented. Experimental and numerical flow modelling demonstrate the potential of the magnetic fields to establish a well-defined flow for tailoring heat and mass transfer in the melt during growth. The results of the growth experiments are discussed with a focus on the influence of a rotating field on the segregation of dopants, the influence of a travelling field on the temperature field and thermal stresses, and the potential of rotating and static fields for a stabilization of the melt flow.

AB - This paper outlines advanced vertical Bridgman/Gradient Freeze techniques with flow control using magnetic fields developed for the growth of semiconductor crystals. Low-temperature flow modelling, as well as laboratory-scaled crystal growth under the influence of rotating, travelling, and static magnetic fields are presented. Experimental and numerical flow modelling demonstrate the potential of the magnetic fields to establish a well-defined flow for tailoring heat and mass transfer in the melt during growth. The results of the growth experiments are discussed with a focus on the influence of a rotating field on the segregation of dopants, the influence of a travelling field on the temperature field and thermal stresses, and the potential of rotating and static fields for a stabilization of the melt flow.

UR - https://www.scopus.com/pages/publications/84875465922

U2 - 10.1140/epjst/e2013-01811-6

DO - 10.1140/epjst/e2013-01811-6

M3 - Review article

AN - SCOPUS:84875465922

SN - 1951-6355

VL - 220

SP - 243

EP - 257

JO - European Physical Journal: Special Topics

JF - European Physical Journal: Special Topics

IS - 1

ER -

The use of magnetic fields in vertical Bridgman/Gradient Freeze-type crystal growth

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