Preparation of GaN Nanocrystals with Single Ag Cores

IF 3.2 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Crystal Growth & Design Pub Date : 2024-09-12 DOI:10.1021/acs.cgd.4c00776

Vojtěch Ćalkovský, Jindřich Mach, Miroslav Bartošík, Jakub Piastek, Marek Kostka, Vojtěch Mikerásek, Linda Supalová, Martin Konečný, Michal Kvapil, Michal Horák, Tomáš Šikola

引用次数: 0

Abstract

We report on a low-temperature hybrid method for the preparation of GaN nanocrystals (NCs) with embedded single Ag cores. GaN growth is realized by a physical vapor deposition of Ga atoms on a SiO₂ substrate with colloidal Ag nanoparticles on its surface, assisted with an ultralow energy (50 eV) nitrogen-ion-beam bombardment at temperatures being significantly lower (T < 350 °C) than in conventional GaN deposition techniques (e.g., MOCVD, 1000°C). We call this method Low Temperature Droplet Epitaxy (LTDE). The low deposition temperature allows GaN nanocrystals to be prepared with embedded metal–aluminum colloidal nanoparticles as their cores. A combination of STEM, SEM, scanning Auger microscopy, XPS, and AFM was applied to characterize semiconductor and metal nanoparticles. By their implementation, we optimized morphology, structure, and chemical composition of these nanocrystals and, consequently, demonstrated their enhanced photoluminescent properties.

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制备具有单个银核的氮化镓纳米晶体

我们报告了一种制备内嵌单个银核的氮化镓（GaN）纳米晶体（NC）的低温混合方法。在超低能量（50 eV）氮离子束轰击的辅助下，镓原子在二氧化硅衬底上进行物理气相沉积，并在其表面形成胶体状的银纳米粒子，其生长温度（T < 350 ℃）明显低于传统的镓沉积技术（如 MOCVD，1000 ℃）。我们称这种方法为低温液滴外延（LTDE）。由于沉积温度低，制备出的氮化镓纳米晶体以嵌入的金属铝胶体纳米粒子为核心。我们结合 STEM、SEM、扫描欧杰显微镜、XPS 和原子力显微镜对半导体和金属纳米粒子进行了表征。通过实施这些方法，我们优化了这些纳米晶体的形态、结构和化学成分，从而证明了它们具有更强的光致发光特性。

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

Crystal Growth & Design 化学-材料科学：综合

CiteScore

6.30

自引率

10.50%

发文量

650

审稿时长

1.9 months

期刊介绍： The aim of Crystal Growth & Design is to stimulate crossfertilization of knowledge among scientists and engineers working in the fields of crystal growth, crystal engineering, and the industrial application of crystalline materials. Crystal Growth & Design publishes theoretical and experimental studies of the physical, chemical, and biological phenomena and processes related to the design, growth, and application of crystalline materials. Synergistic approaches originating from different disciplines and technologies and integrating the fields of crystal growth, crystal engineering, intermolecular interactions, and industrial application are encouraged.