MULTILAYER EPITAXIAL SILICON STRUCTURES WITH SUBMICRON LAYERS GROWN BY SUBLIMATION MOLECULAR BEAM EPITAXI

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Resumo

Multilayer silicon diode structures with basic submicron layers of n- and p-types of conductivity were grown by sublimation molecular beam epitaxy. The distribution profiles of the charge carrier concentrations (electrons and holes) were determined by the volt-farad characteristics method. The use of silicon sublimation sources cut from silicon ingots doped with phosphorus or boron makes it possible to achieve a uniform distribution of charge carrier concentrations over the thickness of the layers and an extremely sharp profile at their boundary with the Si substrate. Such structures can be successfully used for the manufacture of diodes.

Sobre autores

V. Shengurov

Lobachevsky State University

Email: shengurov@phys.unn.ru
Nizhny Novgorod, Russia

A. Titova

Lobachevsky State University

Email: asya_titova95@mail.ru
Nizhny Novgorod, Russia

N. Alyabina

Lobachevsky State University

Email: asya_titova95@mail.ru
Nizhny Novgorod, Russia

V. Chalkov

Lobachevsky State University

Email: asya_titova95@mail.ru
Nizhny Novgorod, Russia

S. Denisov

Lobachevsky State University

Email: asya_titova95@mail.ru
Nizhny Novgorod, Russia

A. Zdoroveyshchev

Lobachevsky State University

Autor responsável pela correspondência
Email: asya_titova95@mail.ru
Nizhny Novgorod, Russia

Bibliografia

  1. Gusyatiner M.S., Gorbachev A.I. Semiconductor ultrahigh frequency diodes. Moscow: Radio and Communications, 1983, 224 p.
  2. Vishnyakova Z.P. Molecular beam epitaxy in semiconductor manufacturing. Reviews on electronic technology ser. 2. Semiconductor devices. Issue 7. – 1985. – P. 128.
  3. Heitzman M., Boudot M. New progress in the development of a 94-6 Hz pretuned module silicon impatt diode // IEEE Trans.Electron Devices. – 1983. – V. 30. – P. 759–763.
  4. Bean J.C. Grow of doped silicon layer by molecular beam epitaxy // Impurity doping / Ed. by FFY Wang-N.Y.: North-Holland. – 1981. – P. 177–215.
  5. Shiraki Y. Silicon molecular beam epitaxy // Ext. Abstr. 15th conf. “Solid-State Devices and Mater” Tokyo. – 1983. – P. 7–10.
  6. Methods of doping silicon layers in the process of sublimation molecular beam epitaxy / V.G. Shengurov, S.P. Svetlov, V.Yu. Chalkov et al. // Physics and technology of semiconductors. – Vol. 2. – 2006. – p. 188–194.
  7. Nutzer J.F., Abstreiter F. Comparison of P and Sb as n-dopants for Si molecular beam epitaxy // J. Appl. Phys. – 1995. – V. 78. – P. 937–940.
  8. Installation for sublimating molecular beam epitaxy of silicon / S.P. Svetlov, V.G. Shengurov, V.A. Tolomasov et al. // Instruments and techniques of experiment. 2001. No. 5. pp. 137–140.
  9. Kuznetsov V.P. On the transfer of P, As, and Al impurities from a silicon source to layers obtained by sublimation in vacuum / V.P. Kuznetsov, V.V. Postnikov // Crystallography. – 1974. – Vol. 2. – p. 346.
  10. Submicron epitaxial silicon layers doped with donor impurities during their evaporation from a silicon melt in vacuum / V.G. Shengurov, V.N. Shabanov, V.A. Rubtsova // Proceedings of the VII Conference on the Processes of Growth and Synthesis of Semiconductor crystals and Films on June 9–13, 1986, Novosibirsk, vol. 1, pp. 273–274.
  11. Shengurov V.G. Multilayer silicon structures obtained by joint evaporation from a solid phase and from a melt // Inorganic materials. – Vol. 37. – 2001. – pp. 783–787.
  12. Boron enrichment of the near–surface region of silicon in the process of sublimation / V.A. Tolomasov, V.V. Vaskin, M.I. Ovsyannikov et al. // Physics and technology of semiconductors, 1981, vol. 15, p. 104.
  13. Autoepitaxial silicon layers obtained by sublimation in vacuum from boron–doped sources / M.I. Ovsyannikov, R.G. Loginova, R.A. Rubtsova, and others // Crystallography. – 1970. – Vol. 6. – p. 1261.

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