Geodesic
Simulation of abnormal radial impurity inhomogeneity formation in space experiments on crystal growth
Matematičeskoe modelirovanie, Tome 21 (2009) no. 10, pp. 67-75 
N. A. Baldina; B. V. Vasekin; V. A. Goncharov. Simulation of abnormal radial impurity inhomogeneity formation in space experiments on crystal growth. Matematičeskoe modelirovanie, Tome 21 (2009) no. 10, pp. 67-75. http://geodesic.mathdoc.fr/item/MM_2009_21_10_a6/
@article{MM_2009_21_10_a6,
     author = {N. A. Baldina and B. V. Vasekin and V. A. Goncharov},
     title = {Simulation of abnormal radial impurity inhomogeneity formation in space experiments on crystal growth},
     journal = {Matemati\v{c}eskoe modelirovanie},
     pages = {67--75},
     year = {2009},
     volume = {21},
     number = {10},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/MM_2009_21_10_a6/}
}
TY  - JOUR
AU  - N. A. Baldina
AU  - B. V. Vasekin
AU  - V. A. Goncharov
TI  - Simulation of abnormal radial impurity inhomogeneity formation in space experiments on crystal growth
JO  - Matematičeskoe modelirovanie
PY  - 2009
SP  - 67
EP  - 75
VL  - 21
IS  - 10
UR  - http://geodesic.mathdoc.fr/item/MM_2009_21_10_a6/
LA  - ru
ID  - MM_2009_21_10_a6
ER  - 
%0 Journal Article
%A N. A. Baldina
%A B. V. Vasekin
%A V. A. Goncharov
%T Simulation of abnormal radial impurity inhomogeneity formation in space experiments on crystal growth
%J Matematičeskoe modelirovanie
%D 2009
%P 67-75
%V 21
%N 10
%U http://geodesic.mathdoc.fr/item/MM_2009_21_10_a6/
%G ru
%F MM_2009_21_10_a6

Voir la notice de l'article provenant de la source Math-Net.Ru

Physical conditions of a well-known space experiment on semiconductor crystal growth are modeled using non-stationary Stephan problem solution. Crystal growth velocity influence on species radial distribution inhomogeneity is analyzed. Numerical results of simulation are going well with experimental data.

[1] Ivanov L. I., Zemskov V. S., Kubasov V. N. i dr., Plavlenie, kristallizatsiya i fazoobrazovanie v nevesomosti, Nauka, M., 1979, 256 pp.

[2] Will A. F., Gatos H. C., Lichtensteiner M., German C. I., “Crystal Growth and segregation under zero gravity: Ge”, J. Electrochem. Soc., 125 (1978), 267–281

[3] Abramov O. V., Okhotin A. S., Chashechkina Zh. Yu. i dr., “Rezultaty issledovaniya kristallov $\mathrm{Pb}_{1-x}\mathrm{In}_x\mathrm{Te}$, poluchennykh metodom Bridzhmena na ustanovke “Kristall” v usloviyakh orbitalnoi stantsii ‘Salyut–6’ ”, Tekhnologicheskie eksperimenty v nevesomosti, Ural. nauchn. tsentr, Sverdlovsk, 1983

[4] Will A. F., Gatos H. C., Lichtensteiner M., German C. I., “Crystal Growth and segregation under zero gravity: Ge”, J. Electrochem. Soc., 125 (1978), 267–281

[5] Danilevsky A. H., Boschert St., Benz K. W., “The effect of the orbital attitude on the mg-growth of InP crystals”, Microgravity Science and Technology. International Journal for Microgravity Research and Applycations, 10:2 (1997), 106–112

[6] Gillies D. C., Lehoczky S. L., Szofran F. R. et al., “Effect of residual acceleration during microgravity directional solidification of mercury cadmium telluride on the USMP-2 mission”, J. Crystal Growth, 174 (1997), 101 | DOI

[7] Zemskov V. S., Belokurova I. N., Khavzhu D. M., “O raspredelenii primesi v poperechnom sechenii kristallov pri napravlennoi kristallizatsii v nevesomosti”, Fizika i khimiya obrabotki materialov, 1985, no. 6, 75–80

[8] Belokurova I. N., Zemskov V. S., Khavzhu D. M., “Analiz rezultatov izucheniya likvatsii komponent v legirovannykh kristallakh germaniya, vyraschennykh napravlennoi kristallizatsiei v usloviyakh nevesomosti i na Zemle”, Fizika i khimiya obrabotki mater., 1990, no. 6, 71–75

[9] Polezhaev V. I., Fedyushkin A. I., “Gidrodinamicheskie effekty kontsentratsionnogo rassloeniya v zamknutykh ob'emakh”, Izv. AN SSSR. Mekhanika zhidkosti i gaza, 1980, no. 3, 11–18

[10] Polezhaev V. I., Bello M. S., Verezub N. A. i dr., Konvektivnye protsessy v nevesomosti, Nauka, M., 1991, 240 pp.

[11] Gershuni G. Z., Zhukhovitskii E. M., Konvektivnaya ustoichivost neszhimaemoi zhidkosti, Nauka, M., 1972, 392 pp.

[12] Marchenko M. P., Fryazinov I. V., “Kompleks programm KARMA1 resheniya nestatsionarnykh zadach vyraschivaniya monokristallov v ampulakh”, Zh. vychisl. matem. i matem. fiz., 37:8 (1997), 988–998

[13] Goncharov V. A., Markov E. V., “Chislennaya skhema modelirovaniya zadach termokonvektsii”, Zh. vychisl. matem. i matem. fiz., 39:1 (1999), 87–97 | MR | Zbl

[14] Rouch P., Vychislitelnaya gidrodinamika, Mir, M., 1980, 616 pp. | Zbl

[15] Davis G. de V., “Natural convection of air in a square cavity: a bench mark numerical solution”, Internat. J. Numer. Methods in Fluids, 1983, no. 3, 249–264 | DOI | Zbl

[16] Goncharov V. A., “Ob odnom metode resheniya dvukhfaznoi zadachi Stefana s neploskoi granitsei”, Zh. vychisl. matem. i matem. fiz., 40:11 (2000), 1706–1715 | MR | Zbl

[17] Loitsyanskii L. G., Mekhanika zhidkosti i gaza, Drofa, M., 2003, 840 pp.