用非接触坩埚法在不接触坩埚壁的情况下生长太阳能电池用多晶硅锭

K. Nakajima, R. Murai, K. Morishita, K. Kutsukake, N. Usami
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引用次数: 1

摘要

使用坩埚的传统晶体生长方法不能控制由于Si熔体凝固而引起的膨胀应力。提出了一种采用传统坩埚的非接触式坩埚方法,降低了Si多晶锭中的应力。在这种方法中,使用种子晶体在Si熔体表面成核,晶体在Si熔体内部生长而不接触坩埚壁。然后,锭继续生长,同时缓慢向上拉,以确保晶体生长保持在Si熔体中。在直径为30厘米的坩埚中获得了直径为23厘米的硅锭。生长时的最大凝固率大于80%。我们已经证实,这种非接触坩埚生长是可能使用传统坩埚。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Growth of multicrystalline Si ingots for solar cells using noncontact crucible method without touching the crucible wall
Conventional crystal growth methods using crucibles cannot control the stress caused by expansion due to the solidification of the Si melt. We proposed a noncontact crucible method using a conventional crucible that reduces the stress in Si multicrystalline ingots. In this method, nucleation occurs on the surface of a Si melt using seed crystals, and crystals grow inside the Si melt without touching the crucible walls. Then, the ingots continue to grow while being slowly pulled upward to ensure that the crystal growth remains in the Si melt. A Si ingot with a diameter of 23 cm was obtained in a crucible with a diameter of 30 cm. The maximum solidification ratio in the growth was more than 80%. We have confirmed that such noncontact crucible growth was possible using a conventional crucible.
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