Synthesis and Properties of Monocrystalline Al(As1鈥?i>xPx)Si3 Alloys on Si(100)

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• 作者：G. Grzybowski ; T. Watkins ; R.T. Beeler ; L. Jiang ; D.J. Smith ; A.V.G. Chizmeshya ; J. Kouvetakis ; J. Men茅ndez
• 刊名：Chemistry of Materials
• 出版年：2012
• 出版时间：June 26, 2012
• 年：2012
• 卷：24
• 期：12
• 页码：2347-2355
• 全文大小：625K
• 年卷期：v.24,no.12(June 26, 2012)
• ISSN：1520-5002

文摘

Semiconductors with the general formula Al(As_1鈥?i>xP_x)Si₃ have been theoretically studied and synthesized. These new materials are grown on Si(100) at 490鈥?00 掳C as single-phase epitaxial layers with monocrystalline diamond-like structures using reactions of Al atomic beams with As(SiH₃)₃ and P(SiH₃)₃ molecular sources. An intriguing outcome of the reaction behavior is that there appears to be no preference in the interaction between Al and the As(SiH₃)₃ and P(SiH₃)₃ coreactants, leading to the organized assembly of the corresponding Al鈥揂s鈥揝i₃ and Al鈥揚鈥揝i₃ building blocks into a tetrahedral lattice in which the P/As atoms are arranged in a common third nearest neighbor sublattice in a manner that precludes the formation of energetically unfavorable Al鈥揂l bonds. The translation of these molecular building blocks into the crystalline structures is elucidated using quantum chemistry. A general crystallographic description for the primitive cell is introduced and used to carry out first principle calculations of the structural, thermodynamic and electronic properties of AlP_1鈥?i>xAs_xSi₃. The results indicate that these materials are indirect gap semiconductors with indirect gaps similar to that of Si but with smaller direct gaps, which should increase their absorption coefficients. Raman spectroscopy provides a qualitative confirmation of these predictions as well as important clues on the orientational order of the tetrahedral building blocks that make up these novel materials. In the context of device design, strain analysis of Al(As_1鈥?i>xP_x)Si₃ indicates that the films are tetragonally compressed due to an inherent 0.8% (or less) lattice mismatch with the Si substrate. At the highest mismatch of 1.6%, strain relaxation is observed for thicknesses exceeding 40 nm, producing prototype layers with bulk-like behavior. Collectively, the results demonstrate that it may be feasible to design and prepare a host of similar systems in this general class of semiconductors with potential optoelectronic applications, including photovoltaics.

Keywords:

semiconductor alloys; III鈭扸 compounds; group-IV semiconductors,