胸腺嘧啶拉曼光谱研究石墨烯薄片和光子晶体结构增强效应

IF 0.7 4区 化学 Q4 CHEMISTRY, MULTIDISCIPLINARY
A. Yaremkevych, O. Fesenko, V. Hryn, P. Yezhov, S. Bellucci, T. Smirnova
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引用次数: 0

摘要

摘要曼光谱学广泛应用于生物有机材料的研究。然而,处理生物样品提出了诸如数量有限、时间紧迫、制备复杂以及需要提高精度等挑战。因此,需要努力提高对特定分子或细胞的敏感性和可视化。本研究以胸腺嘧啶为研究对象,探索了利用周期波导结构(PWS)放大生物分子的拉曼信号。我们发现复合纳米结构显著增强了胸腺嘧啶的拉曼信号,并通过注入石墨烯纳米片进一步增强。这项研究突出了增强拉曼技术在生物分析中的潜力,并为该领域的未来发展铺平了道路。关键词:生物分子石墨烯周期波导结构拉曼光谱乙胺公开声明作者未报告潜在利益冲突。利益声明作者报告无利益冲突需要申报。这项工作得到了乌克兰国家研究基金会在项目2022.01/0011“乌克兰战后重建生物医学方向的创新光子技术”框架下的资助,项目№1.4。В/199“金属-碳纳米结构的光学、等离子体和电物理性质的研究”,北约多年项目SPS G5351“基于纳米复合材料的生物和化学试剂光子晶体传感器”,Fraunhofer IAP内部项目“利用有机-无机纳米复合材料作为无标记光学传感器组件的全息光子晶体的开发”,乌克兰国家科学院基础研究目标计划,项目“纳米物体的激光工程:物理基础与应用”。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Investigation of graphene flake and photonic crystal structure enhancement effect by Raman spectroscopy of thymine
AbstractRaman spectroscopy is widely used for studying bioorganic materials. However, dealing with biological samples presents challenges such as limited quantities, tight timelines, complex preparation, and the need for improved precision. Hence, efforts are needed to enhance sensitivity and visualization for specific molecules or cells. This study explored using periodic waveguide structures (PWS) to amplify Raman signals of biological molecules, focusing on thymine. We found that composite nanostructures significantly boosted thymine’s Raman signal, further enhanced by injecting graphene nanoflakes. This research highlights the potential of enhanced Raman techniques in bioanalysis and paves the way for future advancements in this field.Keywords: Biological moleculesgrapheneperiodic waveguide structuresRaman spectroscopythymine Disclosure statementNo potential conflict of interest was reported by the author(s).Declaration of interest statementThe authors report there are no competing interests to declare.Additional informationFundingThis work was supported by the grant of the National Research Foundation of Ukraine within the framework of the Project 2022.01/0011 "Innovative photonic technologies of bio-medical direction for the post-war reconstruction of Ukraine", the Project №1.4. В/199 “Study of optical, plasmonic, and electrophysical properties of metal-carbon nanostructures”, the NATO Multi-years Project SPS G5351 “Nanocomposite Based Photonic Crystal Sensors of Biological and Chemical Agents”, the internal project of Fraunhofer IAP “Development of holographic photonic crystals using organic-inorganic nanocomposites as components for marker-free optical sensors”, and the Target Program of Fundamental Research of National Academy of Sciences of Ukraine, Project “Laser engineering of nanoobjects: physical foundations and applications”.
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来源期刊
CiteScore
1.20
自引率
14.30%
发文量
248
审稿时长
2 months
期刊介绍: Established in 1966, Molecular Crystals and Liquid Crystals is a world-leading journal publishing original research papers in both an experimental and theoretical nature in three areas of specialization: liquid crystals, molecular crystals, and low-dimensional solids. These cover, but are not limited to: Liquid Crystals: -Electro- and magneto-optical phenomena; thermodynamics; phase transitions; structure; NMR and orientation-controlled spectroscopy; theory. Molecular Crystals: -Spectroscopy; energy and charge transfer; solid state reactions; photo and radiation effects Low-dimensional Solids: -Structure, electronic, magnetic, and optical properties; transport mechanisms The journal publishes research papers, review papers, and book reviews. In all three areas, experimental manuscripts describing both preparation and properties will be considered. Papers that describe determination of crystal structure alone are not encouraged unless some solid state forces (hydrogen bonding, charge transfer, etc.) are playing a significant role and/or some solid state properties of the materials are measured.
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