用于原子荧光测量的高压镓播种器

Thibault F. Guiberti , Matteo Pesarini , Roman Zamchii , Sonu Kumar , Wanxia Zhao , Zeyad T. Alwahabi , Bassam B. Dally
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引用次数: 0

摘要

这项研究介绍了一种基于激光烧蚀的播种器的设计和测试,这种播种器能够在实际燃烧装置中典型的高压条件下将镓粒子引入气流。在这种气流中加入镓粒子是应用 Ga-TLAF 的必要条件,Ga-TLAF 是一种空间和时间分辨的测温成像技术,非常适合恶劣的燃烧环境。首先列出了这种镓粒子播种器的设计标准,然后提供了理解和复制它所需的所有必要细节。接着,利用波长为 403 纳米的镓激光诱导荧光和激光散射测量,验证了镓烧蚀的效率与烧蚀激光的通量、重复率和压力之间的函数关系。对于本研究中用于烧蚀的传统 355 nm 纳秒 Nd:YAG 激光,数据显示,通过改变烧蚀激光的通量和/或其重复率,可以方便地调节流体中的镓种子量。数据还显示,固态镓的消融效率略高于液态镓,但为了避免一段时间后消融效率下降,应优先选择液态镓的消融。液态镓原料的温度并不重要。SEM、EDX 和 SPMS 分析表明,激光烧蚀产生的纯镓颗粒的特征尺寸至少在 50 纳米到 10 微米之间,而且尺寸分布对压力和烧蚀激光的能量不敏感。数据显示,在室温下或火焰的热产物中记录到的镓 LIF 强度不会受到压力的明显影响,这对未来在高压火焰中应用 Ga-TLAF 也非常重要。
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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High-pressure gallium seeder for atomic fluorescence measurements

This work presents the design and testing of a seeder based on laser ablation capable of introducing gallium particles into a gaseous flow at elevated pressures typical of that found in practical combustion devices. The ability to seed such a flow with gallium particles is required to apply Ga-TLAF, a spatially and temporally resolved thermometry imaging technique well suited to harsh combustion environments. The design criteria for this gallium particle seeder are first listed and all the necessary details required to understand and replicate it are then provided. Next, the efficiency of gallium ablation is verified as a function of the ablation laser's fluence and repetition rate and of the pressure using gallium laser induced fluorescence and laser scattering measurements at ∼403 nm. For the conventional 355-nm nanosecond, Nd:YAG laser used for ablation in this study, data show that the quantity of gallium seeded into the flow can be conveniently modulated by varying the fluence of the ablation laser and/or its repetition rate. Data also show that the efficiency of ablation is marginally better for solid gallium than for liquid gallium, but that ablation of liquid gallium should be preferred to avoid a loss of ablation efficiency after some time. The temperature of the liquid gallium feedstock is found to be unimportant. SEM, EDX, and SPMS analyses show that laser ablation yields pure gallium particles with a characteristic size ranging at least from 50 nm to 10 μm and that the size distribution is insensitive to the pressure and to the ablation laser's fluence. Also important for future applications of Ga-TLAF in high-pressure flames, data show that the gallium LIF intensity recorded at room temperature or in the hot products of a flame is not significantly affected by pressure.

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