Design and fabrication of superhydrophobic microstructured grooved substrates to suppress the coffee-ring effect and enhance the stability of Sr element detection in liquids using LIBS.

IF 2.7 3区 化学 Q2 CHEMISTRY, ANALYTICAL
Hongbao Wang, Honglian Li, Xusheng Huang, Zhichao Yao, Huiming Zhang, Yu Hang Yao, Xiaolin Yin, Ziying Chen, Lide Fang
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引用次数: 0

Abstract

A new technique has been developed to enhance the stability of laser-induced breakdown spectroscopy (LIBS) in the analysis of dry droplets by mitigating the coffee ring effect (CRE) on substrates with superhydrophobic microstructured grooves. The substrate was prepared from a laser-etched pure copper base, resembling the surface of a lotus leaf, creating a biomimetic superhydrophobic substrate. The superhydrophobic microstructured grooved substrate contained an array of dome-shaped cones with heights of approximately 140 μm and 100 μm, arranged in a periodic pattern of high-low-high. The superhydrophobic properties of the substrate not only evaporation-induced thermal capillary action but also initiated the Marangoni flow, which moves from the periphery to the center of the droplet as it evaporates. This flow mechanism effectively mitigated the CRE by transporting the analyte from the bottom edge of the droplet across its surface to the central peak. To assess how these superhydrophobic microstructured grooved substrates impede the formation of coffee rings, LIBS was deployed to analyze samples from both structured and unstructured grooved substrates. The results indicated that the relative standard deviation (RSD) of the spectral intensity for Sr I at 407.67 nm in substrates with a superhydrophobic microstructured groove edge length of 0.8 mm was 3.6%. In contrast, for the unstructured grooved substrate and a side length of 0.9 mm, the RSD was significantly higher at 25.4%. This research demonstrates that substrates with superhydrophobic microstructured grooves are capable of effectively mitigating the CRE. Additionally, the study examined how the dimensions of these grooves impact the plasma characteristics across two distinct configurations. Based on these observations, calibration curves for Sr were developed using substrates with groove side lengths of 0.6 mm and 0.8 mm. The performance of the superhydrophobic microstructured grooved substrate was satisfactory, exhibiting determination coefficients (R2) of 0.994 and 0.995 for the Sr element. The detection limits (LOD) were notably low at 0.16 μg mL-1 and 0.11 μg mL-1. The average relative standard deviations (ARSD) were 7.2% and 4.9%, respectively. These results demonstrate that the superhydrophobic microstructured grooved substrate effectively mitigates the CRE, thereby enhancing the detection sensitivity and prediction accuracy for heavy metals. This provides a robust reference for selecting platforms using LIBS technology in the pre-treatment process.

设计和制造超疏水微结构沟槽基底,以抑制咖啡环效应并提高利用 LIBS 检测液体中 Sr 元素的稳定性。
为了提高激光诱导击穿光谱(LIBS)在分析干液滴时的稳定性,我们开发了一种新技术,在具有超疏水微结构凹槽的基底上减轻咖啡环效应(CRE)。基底由激光蚀刻的纯铜基底制备而成,类似于荷叶的表面,形成了仿生物超疏水基底。超疏水性微结构沟槽基底包含高度分别约为 140 微米和 100 微米的圆顶锥阵列,呈高-低-高的周期性排列。基底的超疏水特性不仅使蒸发诱发热毛细作用,还引发了马兰戈尼流,即液滴蒸发时从外围向中心移动。这种流动机制将分析物从液滴底部边缘穿过液滴表面输送到中心峰,从而有效缓解了 CRE。为了评估这些超疏水性微结构沟槽基底如何阻碍咖啡环的形成,我们利用 LIBS 分析了来自结构化和非结构化沟槽基底的样品。结果表明,在超疏水微结构沟槽边长为 0.8 毫米的基底中,407.67 纳米波长处 Sr I 光谱强度的相对标准偏差 (RSD) 为 3.6%。相比之下,对于边长为 0.9 毫米的无结构沟槽基底,RSD 明显更高,为 25.4%。这项研究表明,带有超疏水微结构沟槽的基底能够有效减轻 CRE。此外,研究还考察了这些沟槽的尺寸如何影响两种不同配置的等离子体特性。根据这些观察结果,使用沟槽边长为 0.6 毫米和 0.8 毫米的基底开发了 Sr 的校准曲线。超疏水微结构沟槽基底的性能令人满意,硒元素的确定系数 (R2) 分别为 0.994 和 0.995。检测限(LOD)明显较低,分别为 0.16 μg mL-1 和 0.11 μg mL-1。平均相对标准偏差(ARSD)分别为 7.2% 和 4.9%。这些结果表明,超疏水微结构沟槽基底可有效缓解 CRE,从而提高重金属的检测灵敏度和预测准确性。这为在预处理过程中选择使用 LIBS 技术的平台提供了可靠的参考。
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
Analytical Methods
Analytical Methods CHEMISTRY, ANALYTICAL-FOOD SCIENCE & TECHNOLOGY
CiteScore
5.10
自引率
3.20%
发文量
569
审稿时长
1.8 months
期刊介绍: Early applied demonstrations of new analytical methods with clear societal impact
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