飞秒受激拉曼光谱技术

飞秒受激拉曼光谱（femtosecond stimulated raman spectroscopy,FSRS）是一种新型的非线性振动光谱技术.它使用两束重叠的窄带拉曼泵浦和宽带探测脉冲激光束,利用外差式检波方法在探测光方向上进行信号探测.FSRS既可以用来探测分子电子基态的振动动力学,也可以用来探测分子电子激发态的振动动力学,比如同质异构类反应.即使荧光背景很强的分子,也可以用FSRS来研究.FSRS可以用三阶微扰的波包图像来描绘.单从相位匹配条件出发,共有48项对应于FSRS过程,但是其中只有8项满足共振条件.可以用3种方法来描述这8项：双时间线拉曼图、封闭时间路径环路图和四波混频的能级图.进一步分析表明,这8项可以分成4类,即SRS（I）,SRS（II）,IRS（I）和IRS（II）,其中SRS代表受激拉曼散射,IRS代表反转拉曼散射.SRS（I）可以用来解释自发拉曼散射,但是其余的SRS（II）、IRS（I）和IRS（II）三项只在受激拉曼光谱中存在.FSRS光谱中SRS（I）过程产生的是斯托克斯拉曼谱线,而IRS（I）过程则产生的是反斯托克斯谱线.其余的两项SRS（II）和IRS（II）只是产生很宽的背景基线,基本和我们感兴趣的观测量不相关.使用简谐振动模型,我们可以得到三阶微扰极化率的四时间相关函数的解析表达式.我们讨论了FSRS光谱之所以能够得到高时间分辨率和高频率分辨率的物理原理.在文章中,我们还就以下研究做了计算与实验结果的比较：（a）荧光性罗丹明6G的共振FSRS谱和（b）CDCl3分子非共振脉冲泵浦光制备的相干振动态的二维FSRS谱.计算得到的结果与实验十分吻合,同时在理论上证明了CDCl3二维FSRS光谱中级联效应是占主导作用的.     

拉曼光谱技术在聚合物研究中的应用进展

拉曼光谱可以提供分子的振动信息,对于聚合物分子链的构象和链间的相互作用非常敏感,能够提供聚合物固体、薄膜或溶液的物理化学特性信息,如聚合物的结构单元、空间构型、晶态结构、分子链的物理构象或分子链子链和侧基在界面间或在各向异性材料中的排列等链取向信息等。因此拉曼光谱作为一种原位无损检测技术,其衍生出的表面增强拉曼光谱技术(Surface-enhanced Raman Scattering,SERS)、变温拉曼光谱技术、共焦显微拉曼光谱技术(Confocal Raman Microscopy,CRM)、拉曼Mapping成像技术和共振拉曼散射技术(Resonance Raman scattering,RRS)等,广泛应用于物理、化学和生物医学等领域。本文从拉曼光谱的基本理论基础、拉曼光谱技术及其在聚合物研究中的最新应用进展等方面进行综述,以探索扩展拉曼光谱技术在高分子物理与化学领域中许多问题,如分子链的构象结构、分子链的结晶行为、分子链的扩散运动和共混体系相态结构变化等方面的应用。     

Au@4-硝基苯硫酚@Ag@牛血清白蛋白内标化表面增强拉曼散射探针的制备及其在细胞拉曼成像中的应用

制备了Au@4-硝基苯硫酚@Ag内标化表面增强拉曼散射（SERS）探针,进一步以牛血清白蛋白（BSA）置换探针表面的稳定剂十六烷基三甲基溴化铵（CTAB）,发展了Au@NT@Ag@BSA内标化SERS探针。Au@NT@Ag@BSA探针保留了原探针的单分散性和高灵敏度,同时显著提高了信号稳定性和生物相容性。进一步将Au@NT@Ag@BSA探针和SMMC7721肺癌细胞共孵育,实现了细胞的探针标记和拉曼光谱成像。Au@NT@Ag@BSA内标化SERS探针在活体生物成像等方面展示了良好的应用潜力。     

相干反-斯托克斯喇曼光谱术

相干反斯托克斯喇曼光谱(Coherent Anti-Stokes Raman Spectra,简称CARS)是一种非线性光学混频过程。同时使用两条入射激光束聚焦于样品,输出相当于反-斯托克斯频率光束。量子效率可达1%,散射强度比自发喇曼谱高10~5倍以上,连续CARS谱分辩率为0.01cm~(-1)。这种具有高空间分辩、高抗荧光干扰、高分辩率及高效率等特点的CARS技术,     

拉曼镊子在生物单细胞中的应用与进展

拉曼镊子(Raman tweezers)是将激光光镊(Optical tweezers)与显微拉曼光谱(Raman spectroscopy)结合的光学技术,可以在接近自然状态下研究单个生物细胞或细胞器.因其有无直接接触、无损伤、快速识别、实时追踪等特点,广泛用于生物细胞的识别、探测、筛选等.研究显示,拉曼镊子在微观生物研究的应用中,可提高拉曼光谱的信噪比,也能实现生化动力学过程的实时跟踪,从而能深刻了解细胞内生物大分子的活动规律.本文着重介绍了拉曼镊子的起源、原理及其在单细胞中的应用以及展望.     

基于SERS探针技术的细胞识别、成像与诊疗

表面增强拉曼散射(surface-enhanced Raman scattering, SERS),是指吸附在粗糙的金属纳米结构表面的被分析物,在光照射下其拉曼光谱获得显著增强的异常表面光学现象。近年来,SERS技术已广泛地用于物质检测和生物传感等研究,在生物医学领域表现出巨大的应用潜力并取得了令人瞩目的研究成果。本文回顾了SERS探针技术在细胞识别、成像与诊疗等方面的应用及最新研究进展,重点介绍了SERS细胞探针的构建方法与原理,以及基于SERS探针的细胞检测应用策略,并讨论了SERS探针技术在细胞检测中仍有待解决的关键问题。     

应用于基因分析的最新SERS技术*

表面增强拉曼散射（SERS）是一种基于拉曼散射原理识别生物及化学分子的分析方法。SERS具有灵敏度高、水干扰小、分辨率高、稳定性好等优点,广泛应用于生物分析和生物医学研究领域。近年来,SERS技术在基因分析领域得到迅速的发展,成为国内外研究的热点。本文对应用于基因分析的一些最新SERS技术（包括基因的免标记检测和标记检测）进行较为全面的综述,着重介绍了免标记检测中基于金属纳米粒子和针尖增强拉曼散射的SERS技术,标记检测中基于拉曼活性物、PCR技术、分子信标、基底和标记物的SERS信号放大技术,并概括了基因多组分检测技术及SERS技术的应用前景。     

花状银微纳米结构的合成及SERS性质

通过简便的水溶液方法制备出一种新颖的由纳米片组成的花状银微纳米结构, 采用XRD, SEM, TEM, HRTEM和SAED等手段进行了表征. 考察了反应体系pH值对产物形貌的影响, 并对花状银微纳米结构的形成机理进行了初步探讨. 所制得的微纳米结构由许多纵横交错的纳米片组成. 实验结果表明, 制备的银微纳米结构作为表面增强拉曼散射(Surface-enhanced Raman Scattering, SERS)的基底具有很强的活性.     

硝酸刻蚀银表面的增强拉曼光谱及其在表面化学中的应用

最近,我们摸索出的硝酸刻蚀法制备有SERS(Surface Enhanced Raman Scattering,表面增强拉曼散射)活性的银表面,有良好的热稳定性,且费用低廉,预期在研究金属表面反应、催化和金属-聚合物界面结构等方面可发挥作用。在展示了这一新方法具有极高的表面增强因子后,本文介绍用该法研究吸附质的自集合(self-assembly)和表面取向结果。     

表面增强拉曼散射光谱研究聚苯胺纳米棒的构象转变

采用电化学沉积法制备了聚苯胺(Polyaniline,PANI)纳米棒、树枝状银和纳米颗粒银基体。并利用表面增强拉曼散射光谱技术(Surface-enhanced Raman Scattering,SERS)研究了PANI纳米棒的分子链在Ag金属表面的构象变化。实验结果表明由于Ag金属表面的等离子共振效应,PANI分子中N原子的孤对电子与Ag的自由电子产生共轭效应,使得PANI分子链上的电荷重新分布,结果 C—H面内弯曲振动频率和C—C键的伸缩频率向低波数方向移动(蓝移);拉曼散射频率增强的基团在金属表面倾向垂直于分子链的主轴,拉曼散射频率减弱的基团在金属表面倾向平行于分子链主轴。     

Coherent anti-Stokes Raman scattering microscopy for polymers

Coherent anti-stokes Raman scattering (CARS) microscopy is a label-free chemical imaging modality capable of interrogating local molecular composition, concentration, and even orientation. In comparison to traditional Raman spectroscopy/imaging, CARS generates signals that are typically orders-of-magnitude stronger, enabling high-throughput and large-area imaging with superior spectroscopic fidelity. In this review, we present an overview of CARS microscopy as applied to polymer science, covering such timely and important topics as drug release and reaction kinetics to 3D molecular structures and orientation. We also discuss outstanding opportunities and challenges to using CARS microscopy as a quantitative measurement method.     

Coherent anti-Stokes Raman Scattering Microscopy.

Coherent anti-Stokes Raman scattering (CARS) microscopy is presented as a new nonlinear optical technique. The combination of vibrational spectroscopy and microscopy allows highly sensitive investigations of unlabelled samples. CARS is an ideal tool for studying a broad variety of samples. The main drawback of the technique is its non-zero-background nature, which implies that the signal has to be detected against a nonresonant background. The need to solve this problem is reflected in the rapid technological developments that have been observed during the last decade. Recent results show that CARS microscopy has the potential to become an important complementary technique that can be used with other well-established microscopic methods. Although it has some limitations, it offers unique access to many problems that cannot be tackled with conventional techniques. For this reason, it can be expected that the impressive growth of the field will continue.     

Coherent anti-Stokes Raman scattering: Spectroscopy and microscopy

In this review the basis, recent developments and applications of coherent anti-Stokes Raman scattering (CARS) in the fields of spectroscopy and microscopy are dialed with. The nonlinear susceptibility of the investigated molecule induced by pump and Stokes laser beams employed in the CARS technique is discussed. The relation between the nonlinear susceptibility, the different CARS laser intensities and the phase matching condition between them is also presented. The structure of CARS spectrum is analyzed as a function of the physical characteristics of the different employed lasers. This includes laser half widths, interference effects, cross-coherence and saturation of the resultant CARS signal by stimulated Raman scatter process (SRS). The different broadening mechanisms for CARS spectral line such as pressure and Doppler broadening are demonstrated. The recent progress in CARS for the in situ reaction flame diagnosis due to its suitability for detection of vibrational-rotational excited gas molecules present in the electronic ground state is discussed. CARS diagnosis for liquid- and solid-phases including the progress in polymeric materials is considered. The applications of CARS microscopy are reviewed in the view of its recent advances to study chemical and biological systems.     

Quantitative chemical imaging with multiplex stimulated Raman scattering microscopy

Stimulated Raman scattering (SRS) microscopy is a newly developed label-free chemical imaging technique that overcomes the speed limitation of confocal Raman microscopy while avoiding the nonresonant background problem of coherent anti-Stokes Raman scattering (CARS) microscopy. Previous demonstrations have been limited to single Raman band measurements. We present a novel modulation multiplexing approach that allows real-time detection of multiple species using the fast Fourier transform. We demonstrate the quantitative determination of chemical concentrations in a ternary mixture. Furthermore, two imaging applications are pursued: (1) quantitative determination of oil content as well as pigment and protein concentration in microalgae cultures; and (2) 3D high-resolution imaging of blood, lipids, and protein distribution in ex vivo mouse skin tissue. We believe that quantitative multiplex SRS uniquely combines the advantage of fast label-free imaging with the fingerprinting capability of Raman spectroscopy and enables numerous applications in lipid biology as well as biomedical imaging.     

Live‐Cell Stimulated Raman Scattering Imaging of Alkyne‐Tagged Biomolecules

Alkynes can be metabolically incorporated into biomolecules including nucleic acids, proteins, lipids, and glycans. In addition to the clickable chemical reactivity, alkynes possess a unique Raman scattering within the Raman‐silent region of a cell. Coupling this spectroscopic signature with Raman microscopy yields a new imaging modality beyond fluorescence and label‐free microscopies. The bioorthogonal Raman imaging of various biomolecules tagged with an alkyne by a state‐of‐the‐art Raman imaging technique, stimulated Raman scattering (SRS) microscopy, is reported. This imaging method affords non‐invasiveness, high sensitivity, and molecular specificity and therefore should find broad applications in live‐cell imaging.     

Optical fibre SERS sensors

Surface-enhanced Raman scattering (SERS) has established itself as an important analytical technique. However, efforts to transfer the technology from the laboratory to the production line, clinic or field have been frustrated by the lack of robust affordable substrates and the complexity of interfacing between sample and spectrometer. Prompted by the success of optical fibre systems for implementing normal Raman scattering spectroscopy in remote locations and biomedical applications, attention has now shifted to the development of SERS-active optical fibres. Other workers have attempted to develop SERS probes with extended interaction lengths and both far-field and near-field SERS imaging techniques for high-resolution chemical mapping of surfaces. This review discusses the development of these technologies and presents the current state of the art. Although recent developments show great promise, some outstanding challenges and opportunities remain to be addressed.     

异硫氰基孔雀石绿受激拉曼光谱研究

本文报道了具有时间分辨能力的全频宽带受激拉曼（BBSRS）系统和关于异硫氰基孔雀石绿（MGITC）受激拉曼光谱（sRs）的研究．BBSRS系统的探测光为450-800nm宽带连续白光,泵浦光为280～900nm范围内连续可调谐的ps窄带可见光（带宽≈7．5cm-1,脉宽≈2．5ps）．在合适的泵浦波长下,该系统可同时获取拉曼损失和拉曼增益光谱．MGITC的SRS研究结果表明,当拉曼损失谱峰出现在最大吸收波长（≈627nm）时,共振SRS谱峰强度最大;当泵浦或增益谱峰在最大吸收波长附近时,未观察到明显的共振拉曼信号;共振峰强度随浓度增大而增大,随泵浦功率增大而迅速增大,后趋于饱和;共振和非共振峰强在延时零点附近达到最大值,并随延时绝对值的增大而减小．     

Study of Carbamate‐Modified Disiloxane in Porous PVDF‐HFP Membranes: New Electrolytes/Separators for Lithium‐Ion Batteries

A gel electrolyte membrane is obtained through the absorption of a carbamate‐modified liquid disiloxane‐containing lithium bis(trifluoromethane)sulfonimide (LiTFSI) by using macroporous poly(vinylidene fluoride–hexafluoropropylene) (PVDF‐HFP) membranes. The porous membranes are prepared by means of a phase inversion technique. The resulting gel electrolyte membrane is studied by using differential scanning calorimetry, Fourier‐transform infrared (FTIR) spectroscopy, and microscope mapping through coherent anti‐Stokes Raman scattering (CARS) confocal microscopy and impedance spectroscopy. The ionic conductivity of the gel electrolyte is 10^?4 S cm^?1 at 20 °C. FTIR spectroscopy reveals interactions between LiTFSI and the carbonyl moiety of the disiloxane. No interactions between LiTFSI and PVDF‐HFP or between disiloxane and PVDF‐HFP are detected by FTIR spectroscopy. Furthermore, the distribution of the α and β/γ phases of PVDF‐HFP and the homogeneous distribution of disiloxane/LiTFSI in the gel electrolyte membranes are examined by FTIR mapping. CARS confocal microscopy is used to image the three‐dimensional interconnectivity, which reveals a reticulated structure of macrovoids in the porous PVDF‐HFP framework. Owing to properties such as electrochemical and thermal stability of the disiloxane‐based liquid electrolyte and the mechanical stability of the porous PVDF‐HFP membrane, the gel electrolyte membranes presented herein are promising candidates for applications as electrolytes/separators in lithium‐ion batteries.     

Expanding the Range of Bioorthogonal Tags for Multiplex Stimulated Raman Scattering Microscopy

Multiplex optical detection in live cells is challenging due to overlapping signals and poor signal-to-noise associated with some chemical reporters. To address this, the application of spectral phasor analysis to stimulated Raman scattering (SRS) microscopy for unmixing three bioorthogonal Raman probes within cells is reported. Triplex detection of a metallacarborane using the B−H stretch at 2480–2650 cm⁻¹, together with a bis-alkyne and deuterated fatty acid can be achieved within the cell-silent region of the Raman spectrum. When coupled to imaging in the high-wavenumber region of the cellular Raman spectrum, nine discrete regions of interest can be spectrally unmixed from the hyperspectral SRS dataset, demonstrating a new capability in the toolkit of multiplexed Raman imaging of live cells.