A facile route to synthesize β‐Ga2O3 nanoparticles from γ‐polymorph through a rapid microwave route and their optical properties

IF 1.3 Q3 CHEMISTRY, MULTIDISCIPLINARY

Vietnam Journal of Chemistry Pub Date : 2024-04-23 DOI:10.1002/vjch.202300420

Sadaf Nazir, Saima Masood, S. Shivashankar, Faheem A. Sheikh, Shafquat Majeed

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引用次数: 0

Abstract

Due to the wide bandgap, monoclinic structure and thermodynamic stability, β‐polymorph form of Ga2O3 nanomaterials is well‐received for various applications. However, as the γ‐Ga2O3 is difficult to synthesize, less attention has been paid towards it and its conversion to β‐polymorph. This paper reports the single‐step synthesis of γ‐Ga2O3 using a microwave‐assisted procedure. In this regard, γ‐Ga2O3 powders are synthesized in minutes using benzyl alcohol as the solvent using gallium acetylacetone as the precursor. The XRD of the as‐prepared powders indicates the formation of the γ‐Ga2O3 phase, the very broad peaks indicative of the small crystallite size as confirmed by TEM. The γ‐Ga2O3 powders were annealed at different temperatures and the complete phase conversion of γ‐Ga2O3 phase to β‐Ga2O3 phase happens at 700 °C. The TEM analysis shows the crystallite size to be ≈10 nm for the annealed β‐Ga2O3 phase. The as‐prepared nanopowders show very weak luminescence under excitation and in contrast, a blue‐green emission is observed in case of annealed powders. This confirms the presented strategy as having the potential to use β‐Ga2O3 nanopowders for different optoelectronic applications.

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通过快速微波途径从γ-多晶体合成β-Ga2O3 纳米粒子的简便路线及其光学特性

由于具有宽带隙、单斜结构和热力学稳定性，β-多晶态的 Ga2O3 纳米材料在各种应用中广受欢迎。然而，由于γ-Ga2O3很难合成，因此人们对它及其向β多晶体的转化关注较少。本文报道了利用微波辅助程序一步合成γ-Ga2O3的方法。在这方面，使用苯甲醇作为溶剂，以乙酰丙酮镓作为前驱体，在几分钟内就合成了γ-Ga2O3粉末。所制备粉末的 XRD 表明形成了 γ-Ga2O3 相，经 TEM 证实，非常宽的峰表明结晶尺寸较小。γ-Ga2O3粉末在不同温度下退火，γ-Ga2O3相在700 °C时完全转化为β-Ga2O3相。TEM 分析表明，退火后的β-Ga2O3 相的晶粒尺寸≈10 nm。在激发下，制备的纳米粉体显示出非常微弱的发光，相比之下，退火后的粉体则发出蓝绿色的光。这证实了所提出的策略具有将 β-Ga2O3 纳米粉体用于不同光电应用的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Vietnam Journal of Chemistry CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

1.70

自引率

0.00%

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