LIBS Efficiency Increase via Plasmonic Nanoparticles in the Study of Synthetic Opal Matrices

IF 1.1 4区 物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY
A. N. Maresev, M. A. Shevchenko, N. V. Tcherniega, S. F. Umanskaya, M. A. Karpov, A. D. Kudryavtseva, V. V. Voronova, G. V. Lisichkin
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Abstract

In this article, a method of depositing plasmonic particles on synthetic opal matrices was used for increasing the efficiency of laser-induced breakdown spectroscopy. The fundamental radiation, second and third harmonics of a picosecond neodymium laser were used to generate plasma. The dependences of the gain factor on the size of the laser spot, as well as on the concentration of silver particles, were obtained. The maximum signal amplification exceeding an order of magnitude was achieved at a wavelength of 1064 nm, corresponding to the localization of the plasmon resonance mode in the gap between closely spaced particles. Emission stability when using particles also increases at all laser wavelengths used. Conducted computer simulation confirmed the results of the experiment. High sensitivity of the method allows its use for monitoring even a small amount of impurity elements and their dynamics during the synthesis of photonic crystals, as well as the dynamics of the process of filling them with various materials during infiltration.

Abstract Image

Abstract Image

在合成蛋白石基质研究中通过等离子纳米粒子提高 LIBS 效率
摘要 本文采用了一种在合成蛋白石基质上沉积等离子体粒子的方法,以提高激光诱导击穿光谱的效率。利用皮秒钕激光器的基波辐射、二次谐波和三次谐波产生等离子体。获得了增益因子与激光光斑大小以及银粒子浓度的关系。波长为 1064 纳米时,信号的最大放大率超过了一个数量级,这与等离子体共振模式在间距较近的颗粒之间的间隙中定位有关。在所有使用的激光波长下,使用微粒时的发射稳定性也会增加。计算机模拟证实了实验结果。该方法灵敏度高,可用于监测光子晶体合成过程中即使少量的杂质元素及其动态,以及在浸润过程中填充各种材料的动态。
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
Physics of Wave Phenomena
Physics of Wave Phenomena PHYSICS, MULTIDISCIPLINARY-
CiteScore
2.50
自引率
21.40%
发文量
43
审稿时长
>12 weeks
期刊介绍: Physics of Wave Phenomena publishes original contributions in general and nonlinear wave theory, original experimental results in optics, acoustics and radiophysics. The fields of physics represented in this journal include nonlinear optics, acoustics, and radiophysics; nonlinear effects of any nature including nonlinear dynamics and chaos; phase transitions including light- and sound-induced; laser physics; optical and other spectroscopies; new instruments, methods, and measurements of wave and oscillatory processes; remote sensing of waves in natural media; wave interactions in biophysics, econophysics and other cross-disciplinary areas.
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