Influence of compositional changes of source materials on AlN synthesis using Li-Al-N solvent

T. Nagano; Y. Kangawa; K. Kakimoto

doi:10.1002/pssc.200880908

Influence of compositional changes of source materials on AlN synthesis using Li-Al-N solvent

T. Nagano, Y. Kangawa, K. Kakimoto

Division of Renewable Energy Dynamics

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

We carried out AlN synthesis using Li-Al-N solvent. In the present work, Al and Li₃N were used as source materials. In this paper, we discuss the variation in phase stability of the products with change in Li-Al-N composition, i.e., Al/Li₃N molar ratio. The results suggest that LiAlO₂ extra phase was formed in the products under an Al-rich synthesis condition. The oxide formation seems to be caused by oxidation of the nitrogen source. That is, some of the Li₃N reacted with H₂O in the ambient and to be LiOH, though preparation of the source materials was performed in a glove-box. On the other hand, scanning electron microscopy (SEM) images indicate the possibility of reducing nucleation sites and increasing grain size by optimizing the Al/Li₃N molar ratio.

Original language	English
Pages (from-to)	S336-S339
Journal	Physica Status Solidi (C) Current Topics in Solid State Physics
Volume	6
Issue number	SUPPL. 2
DOIs	https://doi.org/10.1002/pssc.200880908
Publication status	Published - Jul 2009

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1002/pssc.200880908

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title = "Influence of compositional changes of source materials on AlN synthesis using Li-Al-N solvent",

abstract = "We carried out AlN synthesis using Li-Al-N solvent. In the present work, Al and Li3N were used as source materials. In this paper, we discuss the variation in phase stability of the products with change in Li-Al-N composition, i.e., Al/Li3N molar ratio. The results suggest that LiAlO2 extra phase was formed in the products under an Al-rich synthesis condition. The oxide formation seems to be caused by oxidation of the nitrogen source. That is, some of the Li3N reacted with H2O in the ambient and to be LiOH, though preparation of the source materials was performed in a glove-box. On the other hand, scanning electron microscopy (SEM) images indicate the possibility of reducing nucleation sites and increasing grain size by optimizing the Al/Li3N molar ratio.",

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AU - Nagano, T.

AU - Kangawa, Y.

AU - Kakimoto, K.

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N2 - We carried out AlN synthesis using Li-Al-N solvent. In the present work, Al and Li3N were used as source materials. In this paper, we discuss the variation in phase stability of the products with change in Li-Al-N composition, i.e., Al/Li3N molar ratio. The results suggest that LiAlO2 extra phase was formed in the products under an Al-rich synthesis condition. The oxide formation seems to be caused by oxidation of the nitrogen source. That is, some of the Li3N reacted with H2O in the ambient and to be LiOH, though preparation of the source materials was performed in a glove-box. On the other hand, scanning electron microscopy (SEM) images indicate the possibility of reducing nucleation sites and increasing grain size by optimizing the Al/Li3N molar ratio.

AB - We carried out AlN synthesis using Li-Al-N solvent. In the present work, Al and Li3N were used as source materials. In this paper, we discuss the variation in phase stability of the products with change in Li-Al-N composition, i.e., Al/Li3N molar ratio. The results suggest that LiAlO2 extra phase was formed in the products under an Al-rich synthesis condition. The oxide formation seems to be caused by oxidation of the nitrogen source. That is, some of the Li3N reacted with H2O in the ambient and to be LiOH, though preparation of the source materials was performed in a glove-box. On the other hand, scanning electron microscopy (SEM) images indicate the possibility of reducing nucleation sites and increasing grain size by optimizing the Al/Li3N molar ratio.

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Influence of compositional changes of source materials on AlN synthesis using Li-Al-N solvent

Abstract

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