The mathematical model for heat transfer during the Bridgeman crystal growth, using the finite element method and the obtained result are presented. Some modifications to the method were introduced in order to incorporate the data obtained experimentally. Solving the model enabled comparison of the experimental and numerical data and to obtain sufficient accuracy. The model was used to calculate the temperature gradient in the sample and the calculated gradient was in accordance with the observed crystal growth regime.
Keywords:
mathematical model / temperature field / finite element method
TY - JOUR
AU - Perišić, Srđan
AU - Awhida, Ahmed
AU - Radojević, Vesna
AU - Davidović, Dejan
AU - Trifunović, Dejan
AU - Jančić-Heinemann, Radmila
AU - Aleksić, Radoslav
PY - 2015
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2913
AB - The mathematical model for heat transfer during the Bridgeman crystal growth, using the finite element method and the obtained result are presented. Some modifications to the method were introduced in order to incorporate the data obtained experimentally. Solving the model enabled comparison of the experimental and numerical data and to obtain sufficient accuracy. The model was used to calculate the temperature gradient in the sample and the calculated gradient was in accordance with the observed crystal growth regime.
PB - Savez inženjera metalurgije Srbije, Beograd
T2 - Metallurgical & Materials Engineering
T1 - Numerical simulation of temperature field in the vertical bridgman method crystal growth
EP - 33
IS - 1
SP - 25
VL - 21
DO - 10.30544/130
ER -
@article{
author = "Perišić, Srđan and Awhida, Ahmed and Radojević, Vesna and Davidović, Dejan and Trifunović, Dejan and Jančić-Heinemann, Radmila and Aleksić, Radoslav",
year = "2015",
abstract = "The mathematical model for heat transfer during the Bridgeman crystal growth, using the finite element method and the obtained result are presented. Some modifications to the method were introduced in order to incorporate the data obtained experimentally. Solving the model enabled comparison of the experimental and numerical data and to obtain sufficient accuracy. The model was used to calculate the temperature gradient in the sample and the calculated gradient was in accordance with the observed crystal growth regime.",
publisher = "Savez inženjera metalurgije Srbije, Beograd",
journal = "Metallurgical & Materials Engineering",
title = "Numerical simulation of temperature field in the vertical bridgman method crystal growth",
pages = "33-25",
number = "1",
volume = "21",
doi = "10.30544/130"
}
Perišić, S., Awhida, A., Radojević, V., Davidović, D., Trifunović, D., Jančić-Heinemann, R.,& Aleksić, R.. (2015). Numerical simulation of temperature field in the vertical bridgman method crystal growth. in Metallurgical & Materials Engineering
Savez inženjera metalurgije Srbije, Beograd., 21(1), 25-33.
https://doi.org/10.30544/130
Perišić S, Awhida A, Radojević V, Davidović D, Trifunović D, Jančić-Heinemann R, Aleksić R. Numerical simulation of temperature field in the vertical bridgman method crystal growth. in Metallurgical & Materials Engineering. 2015;21(1):25-33.
doi:10.30544/130 .
Perišić, Srđan, Awhida, Ahmed, Radojević, Vesna, Davidović, Dejan, Trifunović, Dejan, Jančić-Heinemann, Radmila, Aleksić, Radoslav, "Numerical simulation of temperature field in the vertical bridgman method crystal growth" in Metallurgical & Materials Engineering, 21, no. 1 (2015):25-33,
https://doi.org/10.30544/130 . .
