White Light Transmission Spectroscopy for Rapid Quality Control Imperfection Identification in Nanoimprinted Surface-Enhanced Raman Spectroscopy Substrates

IF 4.6 Q1 CHEMISTRY, ANALYTICAL

ACS Measurement Science Au Pub Date : 2025-03-01 DOI:10.1021/acsmeasuresciau.5c0000310.1021/acsmeasuresciau.5c00003

Mike Hardy*, Hin On Martin Chu, Serene Pauly, Katie F. Cavanagh, Breandán J.F. Hill, Jason Wiggins, Alina Schilling, Pola Goldberg Oppenheimer, Liam M. Grover, Richard J. Winfield, Jade N. Scott, Matthew D. Doherty, Ryan McCarron, William R. Hendren, Paul Dawson and Robert M. Bowman,

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引用次数: 0

Abstract

Miniaturized biomedical sensor development requires improvements in lithographic processes in terms of cost and scalability. Of particular promise is nanoimprint lithography (NIL), but this can suffer from a lack of high-fidelity pattern reproducibility between master and imprinted substrates. Herein, we present a multidisciplinary investigation into gold- and iron-coated NIL sensors including custom optics and spectroscopy, scanning probe microscopy, and data analysis insights. Polyurethane NIL-made nanodome arrays were interrogated with white light transmission spectroscopy, coupled with principal component analysis (PCA) to investigate potential offsets in the photon-substrate plane interaction angle, an imperfection in NIL substrates. Large-angle mismatches (2–10°) were found to be easily discernible by PCA with statistically significant differences (p = 0.05). Unexpected dips in some spectra are postulated to be due to interacting localized and propagating plasmon polaritons, which is supported with a coupled two-oscillator model. General insights are made regarding the interpretation of PCA loadings, which should be related to physical phenomena, and where maximum variance is not necessarily the most meaningful criterion. Smaller angles (<1°) show no significant differences with overlapping confidence intervals in PCA space. Surface-enhanced Raman spectroscopy (SERS) measurements on gold-coated nanodomes returned relative standard deviations of 6–10% via analysis of gelatin, which is of interest as a nasal lining approximation. Interestingly, nanodomes coated in iron produced small, but useful SERS enhancements, which was subsequently interrogated via scanning thermal probe microscopy showing temperature increases of up to 5 °C over the area of one nanostructure (∼1 μm²). Nanostructures remained intact despite the surprising large local temperature increase relative to a gold-coated comparison sample (∼2 °C). The current study provides a framework for the rapid and accurate quality control assessment of imperfections in NIL-produced nanostructures for sensing applications in SERS and surface plasmon resonance, which may need precisely fabricated nanostructures.

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白光透射光谱用于纳米印迹表面增强拉曼光谱衬底的快速质量控制缺陷识别

小型化生物医学传感器的开发需要在成本和可扩展性方面改进光刻工艺。纳米压印光刻技术（NIL）尤其具有发展前景，但这种技术在母版和压印基底之间缺乏高保真图案重现性。在本文中，我们介绍了对镀金和镀铁 NIL 传感器的多学科研究，包括定制光学和光谱学、扫描探针显微镜和数据分析见解。聚氨酯 NIL 制作的纳米圆顶阵列采用白光透射光谱进行检测，并结合主成分分析 (PCA) 来研究光子与基底平面相互作用角度的潜在偏移，这是 NIL 基底的一个缺陷。PCA 发现，大角度错配（2-10°）很容易辨别，差异具有统计学意义（p = 0.05）。推测某些光谱中的意外凹陷是由于相互作用的局部和传播等离子体极化子造成的，这一点得到了耦合双振荡器模型的支持。对 PCA 负载的解释提出了一般性见解，这些见解应与物理现象相关，而最大方差并不一定是最有意义的标准。在 PCA 空间中，较小的角度（1°）与重叠的置信区间没有明显差异。通过分析明胶，对金涂层纳米块进行的表面增强拉曼光谱（SERS）测量得出的相对标准偏差为 6-10%，而明胶是鼻腔内衬的近似物。有趣的是，涂有铁的纳米块体产生了微小但有用的 SERS 增强，随后通过扫描热探针显微镜对其进行了检测，结果显示在一个纳米结构的面积上（1 μm2）温度最高上升了 5 °C。尽管与涂金的对比样品相比（2 °C），局部温升之大令人吃惊，但纳米结构仍然完好无损。目前的研究为快速、准确地评估 NIL 制成的纳米结构中的缺陷提供了一个框架，这些缺陷可能需要精确制造的纳米结构，用于 SERS 和表面等离子体共振的传感应用。

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

ACS Measurement Science Au 化学计量学-

CiteScore

5.20

自引率

0.00%

发文量

期刊介绍： ACS Measurement Science Au is an open access journal that publishes experimental computational or theoretical research in all areas of chemical measurement science. Short letters comprehensive articles reviews and perspectives are welcome on topics that report on any phase of analytical operations including sampling measurement and data analysis. This includes:Chemical Reactions and SelectivityChemometrics and Data ProcessingElectrochemistryElemental and Molecular CharacterizationImagingInstrumentationMass SpectrometryMicroscale and Nanoscale systemsOmics (Genomics Proteomics Metabonomics Metabolomics and Bioinformatics)Sensors and Sensing (Biosensors Chemical Sensors Gas Sensors Intracellular Sensors Single-Molecule Sensors Cell Chips Arrays Microfluidic Devices)SeparationsSpectroscopySurface analysisPapers dealing with established methods need to offer a significantly improved original application of the method.