激光参数对液态脉冲激光烧蚀合成氧化钆纳米粒子结构特性的影响

IF 1.6 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

The European Physical Journal B Pub Date : 2024-10-04 DOI:10.1140/epjb/s10051-024-00783-4

Mayyadah H. Mohsin, Khawla S. Khashan, Ghassan M. Sulaiman

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引用次数: 0

摘要

本研究深入研究了在液体中通过激光烧蚀和破碎合成的立方氧化钆纳米粒子（c-Gd2O3NPs）的特性，强调了激光能量和波长对纳米粒子形态的影响。FESEM 和 HRTEM 分析表明，在不同的激光通量下，纳米粒子的形态会发生显著变化，包括形成纳米管和纳米片。XRD 分析确定了 c-Gd2O3NPs 的不同物相，其中立方相有明显的反射，单斜相有额外的反射。与基本波长（1064 纳米）相比，使用二次谐波波长（532 纳米）可获得更高的激光能量，从而实现更有效的烧蚀和破碎。这样产生的纳米颗粒更小、更均匀，光学特性也更强，如吸收率和透射率都有所提高。532 纳米波长会显著影响 NPs 的大小和形状，从而产生具有可控大小分布和形态的更小颗粒。这种改变导致了不同的吸收和透射特性，由于量子束缚效应，吸收边缘通常会发生蓝移，即随着颗粒尺寸的减小，能带间隙也会增大。这些发现有助于完善合成过程，加深对 NP 形成机制的理解。这些知识指导了合成过程，并利用 c-Gd2O3NPs 的定制特性提高了其在各种应用中的性能。

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Effect of laser parameters on the structural properties of gadolinium oxide nanoparticles synthesis via pulsed laser ablation in liquid

This study thoroughly investigates the characterization of cubic gadolinium oxide nanoparticles (c-Gd₂O₃NPs) synthesized via laser ablation and fragmentation in liquid, emphasizing the impact of laser fluence and wavelength on nanoparticle morphology. FESEM and HRTEM analyses reveal significant morphological variations, including the formation of nanotubes and nanoflakes, in response to different laser fluences. XRD analysis identifies distinct phases of c-Gd₂O₃NPs, with prominent reflections in the cubic phase and additional reflections in the monoclinic phase. Utilizing a second harmonic wavelength (532 nm) results in higher laser fluence compared to the fundamental wavelength (1064 nm), leading to more efficient ablation and fragmentation. This produces smaller, more uniform nanoparticles with enhanced optical properties, such as increased absorbance and transmittance. The 532 nm wavelength notably influences NPs size and shape, resulting in smaller particles with controlled size distribution and morphology. This modification leads to distinct absorbance and transmittance characteristics, often causing a blue shift in the absorption edge due to the quantum confinement effect, where the energy band gap increases as particle size decreases. These findings contribute to refining the synthesis process and enhancing the understanding of the mechanisms governing NP formation. This knowledge guides the synthesis procedure and harnesses tailored features of c-Gd₂O₃NPs for improved performance in various applications.