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@article{ART001271783},
author={Kyoung-Hee Lee},
title={High resistivity Czochralski-grown silicon single crystals for power devices},
journal={Journal of the Korean Crystal Growth and Crystal Technology},
issn={1225-1429},
year={2008},
volume={18},
number={4},
pages={137-139}

TY - JOUR
AU - Kyoung-Hee Lee
TI - High resistivity Czochralski-grown silicon single crystals for power devices
JO - Journal of the Korean Crystal Growth and Crystal Technology
PY - 2008
VL - 18
IS - 4
PB - The Korea Association Of Crystal Growth, Inc.
SP - 137
EP - 139
SN - 1225-1429
AB - Floating zone, neutron transmutation-doped and magnetic Czochralski silicon crystals are being widely used for fabrication power devices. To improve the quality of these devices and to decrease their production cost, it is necessary to use large-diameter wafers with high and uniform resistivity. Recent developments in the crystal growth technology of Czochralski silicon have enable to produce Czochralski silicon wafers with sufficient resistivity and with well-controlled, suitable concentration of oxygen. In addition, using Czochralski silicon for substrate materials may offer economical benefits. First, Czochralski silicon wafers might be cheaper than standard floating zone silicon wafers. Second, Czochralski wafers are available up to diameter of 300 mm. Thus, very large area devices could be manufactured, which would entail significant saving in the costs. In this work, the conventional Czochralski silicon crystals were grown with higher oxygen concentrations using high pure polysilicon crystals. The silicon wafers were annealed by several steps in order to obtain saturated oxygen precipitation. In those wafers high resistivity over 5,000 Ω·cm is kept even after thermal donor formation annealing.
KW - High resistivity;Czochralski;Silicon;Power devices;Oxygen precipitation
DO -
UR -
ER -

Kyoung-Hee Lee. (2008). High resistivity Czochralski-grown silicon single crystals for power devices. Journal of the Korean Crystal Growth and Crystal Technology, 18(4), 137-139.

Kyoung-Hee Lee. 2008, "High resistivity Czochralski-grown silicon single crystals for power devices", Journal of the Korean Crystal Growth and Crystal Technology, vol.18, no.4 pp.137-139.

Kyoung-Hee Lee "High resistivity Czochralski-grown silicon single crystals for power devices" Journal of the Korean Crystal Growth and Crystal Technology 18.4 pp.137-139 (2008) : 137.

Kyoung-Hee Lee. High resistivity Czochralski-grown silicon single crystals for power devices. 2008; 18(4), 137-139.

Kyoung-Hee Lee. "High resistivity Czochralski-grown silicon single crystals for power devices" Journal of the Korean Crystal Growth and Crystal Technology 18, no.4 (2008) : 137-139.

Kyoung-Hee Lee. High resistivity Czochralski-grown silicon single crystals for power devices. Journal of the Korean Crystal Growth and Crystal Technology, 18(4), 137-139.

Kyoung-Hee Lee. High resistivity Czochralski-grown silicon single crystals for power devices. Journal of the Korean Crystal Growth and Crystal Technology. 2008; 18(4) 137-139.

Kyoung-Hee Lee. High resistivity Czochralski-grown silicon single crystals for power devices. 2008; 18(4), 137-139.

Kyoung-Hee Lee. "High resistivity Czochralski-grown silicon single crystals for power devices" Journal of the Korean Crystal Growth and Crystal Technology 18, no.4 (2008) : 137-139.