Spectroscopy Applications(光谱学应用)研究综述
Spectroscopy Applications 光谱学应用 - Multimode fibers (MMFs) show great promise as miniature probes for sensing, imaging, and spectroscopy applications. [1] However the shape of CARS spectra is generally complex because of the combination of both resonant and non-resonant contributions, which limits the development of CARS microspectroscopy applications. [2] This property facilitates the potential of sources suitable for sensing and spectroscopy applications. [3] This approach provides comb multiplication with different line spacing and generation of dual-comb for spectroscopy applications. [4] The 128x1 linear array is perfectly suited for spectroscopy applications, particularly for advanced Raman techniques, thanks to on-chip time-gating and time-tagging capabilities. [5] Moreover, this coupling effect is useful for the improvement of Raman spectroscopy efficiency and its spectroscopy applications. [6] Potential energy surfaces fit with basis set expansions have been shown to provide accurate representations of electronic energies and have enabled a variety of high-accuracy dynamics, kinetics, and spectroscopy applications. [7] 7 A CW gyrotron is developed for the spectroscopy applications. [8] The proposed framework is suitable for high-performance lensless imaging systems for on-chip microscopy and spectroscopy applications. [9] 5 μm to 13 μm, which covers the molecular fingerprint region relevant for many spectroscopy applications. [10] 7 A CW gyrotron is developed for the spectroscopy applications. [11] Optoelectronic modulators that operate by the electrical tuning of plasmonic resonator structures have demonstrated fast (>MHz) manipulation of terahertz (THz) radiation for communications, imaging, and spectroscopy applications. [12] In the pulsed laser photoacoustic (PA) detection and spectroscopy applications, the fundamental frequency of the PA signal produced, and the sensor resonance frequency should be as close as possible to each other so that analyzes from the obtained signals can be performed effectively. [13] The large locking range of the transmitting signal shows promising results for spectroscopy applications, which can be used for material detection and analysis. [14] Technologies and industrials in imaging, security detection, and spectroscopy applications are still in great need of much higher output power THz source. [15] measurement time in spectroscopy applications. [16] The reflectance and photometric data collected and released here enable the use of these color standards for calibration of data from Mastcam-Z and other Mars-2020 rover instruments as well as provide key information for many other imaging and spectroscopy applications that require the calibration of data from multiple lighting or viewing geometries. [17] Superluminescent diodes (SLDs) with high power spectral density present an appealing low cost, small footprint and relatively simple alternative to supercontinuum sources for spectroscopy applications that do not require extremely broad optical spectra1. [18] Elastically bent single crystal Laue case diffraction crystals provide interesting new opportunities for imaging and spectroscopy applications. [19] In this paper, we review recent developments of swept-wavelength lasers based on GaSb type-I gain-chip technology, their key performance parameters for spectroscopy applications and provide experimental data on spectroscopic sensing of the key biomolecules both in synthetic solutions as well as whole blood. [20] SC generation in all-normal dispersion fibers can under certain requirements provide a highly coherent spectrum [2, 3], which is of key importance to a large range of imaging and spectroscopy applications. [21] These results prove versatility and viability of this new technological platform for integrated THz sensing and spectroscopy applications. [22] The longitudinal relaxation constants (T1 ) for the labeled acetyl and carboxyl carbonyls were approximately 30 seconds, supporting in vivo imaging and spectroscopy applications. [23] Since the quantum cascade laser (QCL) has become the dominant laser source in the mid-infrared portion of the electromagnetic spectrum, where fundamental absorption lines of many molecules lie, it is of great use particularly in spectroscopy applications. [24] Spoof surface plasmon polariton waveguides are perfect candidates to enable novel, miniaturized terahertz integrated systems, which will expedite the next-generation ultra-wideband communications, high-resolution imaging and spectroscopy applications. [25] Nano-antennas are used in optical data storage, near-field imaging, photovoltaics, sensing, and spectroscopy applications. [26] Gas-filled Hollow Core Photonic Cristal Fibres (HCPCF) or Photonic MicroCell (PMC) [1] has proven to offer an outstanding gas-cell for laser metrology and spectroscopy applications. [27]多模光纤 (MMF) 作为用于传感、成像和光谱应用的微型探针显示出巨大的前景。 [1] 然而,由于共振和非共振贡献的结合,CARS光谱的形状通常很复杂,这限制了CARS显微光谱应用的发展。 [2] 这一特性促进了适用于传感和光谱应用的源的潜力。 [3] 这种方法为光谱应用提供了具有不同线间距的梳状乘法和双梳状的生成。 [4] 由于片上时间门控和时间标记功能,128x1 线性阵列非常适合光谱应用,特别是高级拉曼技术。 [5] 此外,这种耦合效应有助于提高拉曼光谱效率及其光谱应用。 [6] 与基组展开相匹配的势能表面已被证明可以提供电子能量的准确表示,并已实现各种高精度动力学、动力学和光谱学应用。 [7] 7 为光谱应用开发了一个 CW 回旋管。 [8] 所提出的框架适用于片上显微镜和光谱应用的高性能无透镜成像系统。 [9] 5 μm 至 13 μm,涵盖与许多光谱应用相关的分子指纹区域。 [10] 7 为光谱应用开发了一个 CW 回旋管。 [11] 通过等离子体谐振器结构的电调谐操作的光电调制器已经证明了用于通信、成像和光谱应用的太赫兹 (THz) 辐射的快速 (>MHz) 操纵。 [12] 在脉冲激光光声 (PA) 检测和光谱应用中,产生的 PA 信号的基频和传感器谐振频率应尽可能接近,以便有效地对获得的信号进行分析。 [13] 发射信号的大锁定范围在光谱应用中显示出有希望的结果,可用于材料检测和分析。 [14] 成像、安全检测和光谱应用中的技术和工业仍然非常需要更高输出功率的太赫兹源。 [15] 光谱应用中的测量时间。 [16] 此处收集和发布的反射率和光度数据使这些颜色标准能够用于校准 Mastcam-Z 和其他 Mars-2020 漫游车仪器的数据,并为需要校准数据的许多其他成像和光谱应用提供关键信息来自多个照明或查看几何图形。 [17] 对于不需要极宽光谱的光谱应用,具有高功率光谱密度的超发光二极管 (SLD) 是一种有吸引力的低成本、小尺寸和相对简单的超连续谱源替代品。 [18] 弹性弯曲单晶劳厄案例衍射晶体为成像和光谱应用提供了有趣的新机会。 [19] 在本文中,我们回顾了基于 GaSb I 型增益芯片技术的扫频激光器的最新发展,它们在光谱应用中的关键性能参数,并提供了合成溶液和整个关键生物分子光谱传感的实验数据。血液。 [20] 在某些要求下,全正常色散光纤中的 SC 生成可以提供高度相干的光谱 [2, 3],这对于大范围的成像和光谱应用至关重要。 [21] 这些结果证明了这种用于集成太赫兹传感和光谱应用的新技术平台的多功能性和可行性。 [22] 标记的乙酰基和羧基羰基的纵向弛豫常数 (T1) 约为 30 秒,支持体内成像和光谱学应用。 [23] 由于量子级联激光器 (QCL) 已成为电磁光谱中红外部分的主要激光源,许多分子的基本吸收线位于该部分,因此在光谱学应用中特别有用。 [24] 欺骗表面等离子体激元波导是实现新型、小型化太赫兹集成系统的完美候选者,这将加速下一代超宽带通信、高分辨率成像和光谱学应用。 [25] 纳米天线用于光学数据存储、近场成像、光伏、传感和光谱应用。 [26] 充气空心光子晶体光纤 (HCPCF) 或光子微电池 (PMC) [1] 已被证明可以为激光计量和光谱应用提供出色的气体电池。 [27]
Infrared Spectroscopy Applications 红外光谱应用
The success of infrared spectroscopy applications for quantitative analysis of phytochemicals and adulterants content in plant-based medicine and supplement can happen by several factors. [1] Significance: Despite its advantages in terms of safety, low cost, and portability, functional near-infrared spectroscopy applications can be challenging due to substantial signal contamination from hemodynamics in the extracerebral layer (ECL). [2] The supercontinuum generation based on self-frequency shift (SFS) of Raman solitons in various optical fibres is a technology to provide promising spectra for infrared spectroscopy applications. [3] Promoting artificial and functional metamaterial designs with large electromagnetic near-field enhancement especially over throughout multiband spectral range can provide critical contributions for infrared spectroscopy applications. [4] In near-infrared spectroscopy applications, the original spectra often contain redundant information, which will seriously affect the performance of chemometric models. [5] Preprocessing is important for near infrared spectroscopy applications as it reduces noise and improves prediction accuracy of models. [6] A new type of photoelectric detector based on a standard quartz crystal tuning fork (QCTF) with resonant frequency of ∼32 kHz is developed for infrared spectroscopy applications. [7]红外光谱应用在植物性药物和补充剂中植物化学物质和掺杂物含量的定量分析中的成功可能与几个因素有关。 [1] 意义:尽管在安全性、低成本和便携性方面具有优势,但由于脑外层 (ECL) 中血流动力学的大量信号污染,功能性近红外光谱应用可能具有挑战性。 [2] 基于各种光纤中拉曼孤子的自频移(SFS)的超连续谱生成是一种为红外光谱应用提供有前景的光谱的技术。 [3] 促进具有大电磁近场增强的人工和功能超材料设计,特别是在整个多波段光谱范围内,可以为红外光谱应用提供关键贡献。 [4] 在近红外光谱应用中,原始光谱往往包含冗余信息,这将严重影响化学计量模型的性能。 [5] 预处理对于近红外光谱应用很重要,因为它可以降低噪声并提高模型的预测精度。 [6] 为红外光谱应用开发了一种基于标准石英晶体音叉(QCTF)的新型光电探测器,谐振频率为~32kHz。 [7]
Raman Spectroscopy Applications 拉曼光谱应用
In this study, a custom system that is capable of switching between two spatially offset Raman excitation modes, namely inverse (iSORS, ring) and diffuse (dSORS, enlarged flat-top circle), were compared at the same power for depth-probing Raman spectroscopy applications. [1] DC sputtered bismuth thin film was fabricated for Surface Enhanced Raman Spectroscopy applications as an alternative to the existing platforms. [2] As such, our framework could enable a host of higher-throughput spontaneous Raman spectroscopy applications across a diverse range of fields. [3] This review is a summary of the Raman spectroscopy applications made over the last 10 years in the field of cellulose and lignocellulose materials. [4] This present review briefly evaluates Raman spectroscopy applications in the quality and safety analysis of oil products in the latest decade. [5]在这项研究中,能够在两种空间偏移拉曼激发模式之间切换的定制系统,即逆(iSORS,环)和漫射(dSORS,扩大平顶圆),在相同功率下对深度探测拉曼进行了比较光谱应用。 [1] 直流溅射铋薄膜被制造用于表面增强拉曼光谱应用,作为现有平台的替代品。 [2] 因此,我们的框架可以在不同领域实现大量高通量自发拉曼光谱应用。 [3] 这篇综述总结了过去 10 年在纤维素和木质纤维素材料领域的拉曼光谱应用。 [4] 本综述简要评估了近十年来拉曼光谱在石油产品质量和安全分析中的应用。 [5]
Molecular Spectroscopy Applications 分子光谱学应用
Such a few-cycle fiber laser could be an ideal candidate source for short-wavelength mid-infrared frequency metrology and molecular spectroscopy applications. [1] These results demonstrate the tuning finesse and phase-noise characteristics of the integrated circuit embedded phase lock loop used to generate coherent mm-wave radiation are sufficient for high-precision molecular spectroscopy applications. [2] Such results demonstrate that such sources are suitable for compact, chip-integrated molecular spectroscopy applications. [3] The extension of the available spectral range covered by quantum cascade lasers (QCL) would allow one to address new molecular spectroscopy applications, in particular in the long wavelength domain of the mid-infrared. [4]这种少周期光纤激光器可能是短波长中红外频率计量和分子光谱应用的理想候选光源。 [1] 这些结果表明,用于产生相干毫米波辐射的集成电路嵌入式锁相环的调谐精度和相位噪声特性足以满足高精度分子光谱应用。 [2] 这样的结果表明,这样的源适用于紧凑的、芯片集成的分子光谱学应用。 [3] nan [4]
Imaging Spectroscopy Applications
Acousto-optical tunable filters (AOTFs) based on interaction of light and ultrasound in uniaxial birefringent crystals are widely used in imaging spectroscopy applications due to random spectral access, narrow controllable bandwidth, compactness, overal ease-of-use and image trasmittance capability. [1] Owing to the use of simple optical elements, the design can serve as the basis for making inexpensive devices for a wide range of spatially resolved imaging spectroscopy applications. [2] The devices based on the dual-channel AOTF-based stereoscopic system may be effectively used for various 3D imaging spectroscopy applications. [3]基于光和超声波在单轴双折射晶体中相互作用的声光可调谐滤波器 (AOTF) 因其随机光谱访问、窄可控带宽、紧凑性、整体易用性和图像透射能力而广泛用于成像光谱应用。 [1] 由于使用了简单的光学元件,该设计可以作为为广泛的空间分辨成像光谱应用制造廉价设备的基础。 [2] 基于双通道 AOTF 立体系统的设备可以有效地用于各种 3D 成像光谱应用。 [3]
Ray Spectroscopy Applications
X-ray spectroscopy applications are extended to include the time-resolved study of reactions caused by temperature jumps in aqueous solutions. [1] Eu2+-doped mixed halide scintillators, CsSrBrI2, CsCaBrI2 and CsSrClBr2 were studied for gamma-ray spectroscopy applications. [2] We present here a 16-channels ASIC for SiPMs readout in gamma-ray spectroscopy applications. [3]X 射线光谱学应用扩展到包括对水溶液中温度跳跃引起的反应的时间分辨研究。 [1] 研究了 Eu2+ 掺杂的混合卤化物闪烁体、CsSrBrI2、CsCaBrI2 和 CsSrClBr2 用于伽马射线光谱学应用。 [2] 我们在这里展示了一个 16 通道 ASIC,用于在伽马射线光谱应用中读取 SiPM。 [3]
Optical Spectroscopy Applications
In order to evaluate the optical efficiency of tip-based probes for future tip-enhanced optical spectroscopy applications, we have developed an experimental setup based on the coupling of an achromatic inverted microscope equipped with a total internal reflection objective and an atomic force microscopy (AFM) head. [1] 55~\mu \text{m}$ to enable integration of quantum cascade lasers (QCLs) and detectors with slotted photonic crystal waveguide (PCW) gas sensors for on-chip optical spectroscopy applications. [2]为了评估基于尖端的探针在未来尖端增强光谱应用中的光学效率,我们开发了一种基于配备全内反射物镜的消色差倒置显微镜和原子力显微镜 (AFM) 耦合的实验装置) 头。 [1] 55~\mu \text{m}$ </tex-math></inline-formula> 实现量子级联激光器 (QCL) 和探测器与用于片上光谱学的开槽光子晶体波导 (PCW) 气体传感器的集成应用程序。 [2]
Enhanced Spectroscopy Applications
The magnetic field enhancement of these structures can be utilized in studying magnetic dipole transitions, magnetic imaging, chirality, and enhanced spectroscopy applications. [1] Despite being tuned at the broad spectral range, the S11 mode demonstrated minimal decrease in its near field enhancement characteristics, which can be advantageous for surface-enhanced spectroscopy applications and device fabrication perspectives. [2]这些结构的磁场增强可用于研究磁偶极跃迁、磁成像、手性和增强光谱应用。 [1] 尽管在宽光谱范围内进行了调谐,但 S11 模式在其近场增强特性方面表现出最小的下降,这对于表面增强光谱应用和器件制造方面可能是有利的。 [2]
Nmr Spectroscopy Applications
185 THz (wavelength about $\pmb{250\ \mu}\mathbf{m}$) and an output power of 100–200 W, intended for DNP/NMR spectroscopy applications is described. [1] The tapered RF interaction cavity of 140 GHz tunable continuous wave (CW) gyrotron operating in TE0,3,q mode has been tailored with the aim of providing RF power over a tunable bandwidth for 212 MHz DNP NMR spectroscopy applications. [2]描述了 185 THz(波长约为 $\pmb{250\\mu}\mathbf{m}$)和 100-200 W 的输出功率,用于 DNP/NMR 光谱应用。 [1] 在 TE0,3,q 模式下工作的 140 GHz 可调谐连续波 (CW) 回旋加速器的锥形射频相互作用腔经过定制,旨在为 212 MHz DNP NMR 光谱应用提供可调带宽上的射频功率。 [2]