激光剥蚀电感耦合等离子体质谱新进展

简单介绍了激光剥蚀电感耦合等离子体质谱(LA-ICP-MS)的基本原理及装置。分别对LA-ICP-MS在飞秒激光器、紫外激光器、固液气溶胶混合进样、集合式小样品标样、原位统计分布技术上的技术新进展进行了详细的评述。最后对LA-ICP-MS在元素含量分析与空间分布分析中所占的地位及其应用前景进行了展望。     

激光剥蚀电感耦合等离子体质谱微区分析新进展

从仪器、基础研究诸方面评述近年来LA-ICP-MS微区分析进展,重点介绍了与ICP-MS联用的激光技术发展、校正方法、分馏效应、剥蚀颗粒分布研究及仪器装置与实验技术与改进,对LA-ICP-MS技术的应用作了回顾与展望。     

激光剥蚀电感耦合等离子体质谱在生物样品定量分析中的研究进展

激光剥蚀-电感耦合等离子体质谱(LA-ICP-MS)作为一种可以直接分析固体材料的元素含量和同位素比值的分析技术,已经历了30多年的迅速发展。本文首先简要介绍了LA-ICP-MS的仪器装置,之后阐述了LA-ICP-MS定量分析中的基体效应、分馏效应以及定量校正方法,重点介绍了其在生物医学研究中的应用。最后对LA-ICP-MS的发展方向和应用前景进行了展望。     

LA-ICP-MS锆石U-Pb同位素定年存在的基体效应研究进展北大核心CSCD

激光剥蚀电感耦合等离子体质谱法(LA-ICP-MS)是开展锆石微区原位U-Pb同位素定年研究的重要技术方法。LA-ICP-MS锆石U-Pb同位素定年存在的基体效应是影响其分析结果准确度和精密度的主要因素。依据前人有关基体效应的研究成果,总结了基体效应的类型主要有元素基体效应、高铀或高D_(dpa)基体效应以及α通量基体效应,详细阐述了各种基体效应的性质和产生机理,探讨了已建立的基体效应应对策略存在的问题和不足(引用文献46篇)。     

LA-ICP-MS锆石U-Pb同位素定年存在的基体效应研究进展

激光剥蚀电感耦合等离子体质谱法(LA-ICP-MS)是开展锆石微区原位U-Pb同位素定年研究的重要技术方法。LA-ICP-MS锆石U-Pb同位素定年存在的基体效应是影响其分析结果准确度和精密度的主要因素。依据前人有关基体效应的研究成果,总结了基体效应的类型主要有元素基体效应、高铀或高D_(dpa)基体效应以及α通量基体效应,详细阐述了各种基体效应的性质和产生机理,探讨了已建立的基体效应应对策略存在的问题和不足(引用文献46篇)。     

激光剥蚀串联电感耦合等离子体质谱在环境分析中的应用进展

激光剥蚀串联电感耦合等离子体质谱法(LA-ICP-MS)是一种功能强大的化学元素检测方法,它具有样品前处理简单、多元素同时测定、高通量、高灵敏度、宽线性范围以及原位分析等优点。同时,激光剥蚀可以与多接收器电感耦合等离子体质谱仪(MC-ICP-MS)串联用于稳定同位素组成测定,不仅避免了繁琐的样品前处理,同时还可应用于固体样品的微区原位同位素分析,揭示微观尺度上稳定同位素组成的变化。LA-ICP-MS已广泛应用于地质、考古等领域,其在环境科学领域应用相对起步较晚,但近年来发展迅速。该文总结了近年来LA-ICP-MS的环境分析方法开发及其在环境科学中的应用进展,并对其未来发展趋势进行了展望。     

激光烧蚀光谱-电感耦合等离子体质谱联用技术应用进展

激光烧蚀光谱（LAS）分析技术具有简便快速的特点,仪器设备简便,但对痕量元素分析能力不足。电感耦合等离子体质谱(ICP-MS)分析技术则具有灵敏度高和多元素及同位素分析能力,但对基体元素分析存在困难。将LAS和ICP-MS分析技术相结合构成LAS-ICP-MS联用分析技术,可相互弥补LAS和ICP-MS技术的缺陷。介绍了近10年来LAS-ICP-MS联用技术的应用进展及发展趋势,并详细阐述了近年来LA-ICP-MS分别在地质、矿冶、材料、环境监测以及其它分析领域的应用。     

同位素稀释-激光剥蚀-电感耦合等离子体质谱法测定生物组织样品中铁元素的含量

针对目前采用同位素稀释-激光剥蚀-电感耦合等离子体质谱(ID-LA-ICP-MS)对固体生物组织切片样品难以实现原位准确定量的难题,本研究将同位素稀释法与LA-ICP-MS技术相结合,通过开展生物组织样品与浓缩稀释剂的同位素充分交换平衡、稀释剂添加方式、原位的同位素比测量等关键技术研究,确定了组织切片与同位素稀释剂的最佳平衡时间、稀释剂的质量以及选用甲醇作为稀释剂溶剂等实验条件,建立了基于同位素稀释技术的LA-ICP-MS技术在生物样品组织切片中Fe元素的微区定量分析方法,并采用实验室自行制备的均匀的山羊脑和牛肝组织切片标准样品对方法进行了验证,通过ID-LA-ICP-MS方法的测量结果与微波消解-同位素稀释方法的测量结果相一致,验证了该方法的有效性和可靠性。本方法可进一步应用于临床中生物组织切片样品中金属元素的原位、微区定量测量及成像分析。     

激光剥蚀电感耦合等离子体质谱在涂料重金属分析中的应用

将激光剥蚀进样技术(LA)与ICP-MS检测器联用,并将这一新技术应用在涂料重金属元素的检测上,通过优化LA和ICP-MS参数,并采用双气流校正技术,以13C、103Rh为双内标,有效地改善了信号强度和稳定性,同时对Hg的记忆效应进行研究,最终建立了LA-ICP-MS法测定涂料中Cr、As、Cd、Sn、Sb、Hg、Pb元素的定量分析方法,样品测定结果与湿法消解ICP-OES法基本吻合。     

激光剥蚀电感耦合等离子体质谱(LA-ICP-MS)法测定涂层氧化锆颗粒铌层中24种微量杂质元素

本文针对涂层氧化锆颗粒涂层分析需求,建立了LA-ICP-MS分析Nb涂层和Zr基质中24种微量杂质元素测试方法,获得了最佳剥蚀条件(激光束斑44微米、能量密度6J/cm2、剥蚀频率5 Hz);并利用NIST610标样作为外标、Nb和Zr作内标分别校正了Nb涂层及Zr基质层;方法检出限: 1.5μg/g (Fe)、1.16 (Cr)、0.36(Ni),其它21中元素检出限0.01 ~695.72μg/g。该方法成功测定了60件Nb涂层和Zr基质样品中24种微量杂质元素;获得了26种元素深度剥蚀信号vs时间轮廓图,激光剥蚀涂层时间为16～110s;建立了涂层厚度测试方法,利用LA-ICP-MS技术结合环境扫描电镜能谱技术测定了球体涂层的厚度, 获得了准确的LA深度剥蚀率0.3714μm/s,并成功测定了60件样品中涂层的厚度(5.942~40.854 μm),实现了涂层氧化锆涂层成分定量。     

Determination of Low Interfacial Tension with a Laser Light Scattering Technique and a Comparative Analysis with Drop Shape Methods

A comparative analysis of laser light scattering and drop shape techniques for measuring low interfacial tension is provided with particular reference to the gas condensate systems in petroleum reservoirs. Measurements of interfacial tensions for two real reservoir gas condensate samples were undertaken at elevated pressure and temperature reservoir conditions with the laser light scattering technique. The purposes of this study are (a) to clarify some existing confusion on the usefulness of three major interfacial tension measurement methods, pendant drop, spinning drop, and laser light scattering; and (b) to show the applicability of the laser light scattering technique to real reservoir gas condensate interfaces at low interfacial tensions. The laser light scattering technique has appeared to be the most suitable approach for the determination of low gas condensate interfacial tensions at reservoir conditions in terms of precision and operation. Copyright 2001 Academic Press.     

PMMA基微流控芯片的准分子激光制备方法研究

采用准分子激光微加工技术在PMMA表面加工出了微混合器芯片.实验结果表明,采用准分子激光微加工技术可以加工出尺寸基本符合要求的、连续的、表面光洁度髙和边界整齐的微通道,可以加工出结构复杂的微流控芯片.     

Evaluation of laser ablation optical emission spectrometry for microanalysis in aluminium samples

This paper presents the first evaluation of laser ablation optical emission spectrometry for elemental microanalysis in solids. All the measurements have been performed on aluminum, a matrix in which elements segregate very easily. The lateral resolution obtained is close to 6 μm. It has been evaluated both by making replicas of the small craters formed in aluminum and by making a profile of the intensity distribution of two lines (Al and Cu) across a sharp junction of these two metals. A strong dependence of the measurement reproducibility on the laser energy fluctuations has been observed. Intrinsic reproducibility of the technique has been evaluated at 8% using a stable laser source. The detection limit is around 4 ppm for Mg and 40 ppm for Cu. This surprisingly high sensitivity is mainly attributed to a very efficient coupling between the UV laser beam and the solid surface, leading to crater depths of around 5 μm for a single laser shot. Calibration curves obtained for Mg and Cu using specially fabricated samples demonstrate that the technique is quantitative and not strongly sensitive to the matrix composition. These results demonstrate the very high potential of laser ablation optical emission spectrometry for elemental microanalysis, opening a wide field of applications for this technique.     

Matrix-assisted pulsed laser evaporation of polyimide thin films and the XPS study

Compared with the traditional thin film techniques, the matrix-assisted pulsed laser evaporation (MAPLE) technique has many advantages in the deposition of polymer and organic thin films. It has a wide range of applications in many fields, such as non-linear optics, luminescent devices, electronics, various sensors. We have successfully deposited polyimide thin films by using the MAPLE technique. These films were characterized with XPS. The XPS spectra showed that the single-photon effect is ob-vious at low laser fluence and the chemical bonds will be broken, resulting in decomposition of the films. Contrarily, the single-photon effect will decrease and the multi-photon effect and the photothermal effect will increase at high laser fluence, resulting in the protection of the structure of the polyimide thin films and the obvious decrease in decomposition. High laser fluence is more suitable for the deposition of polymer and organic thin films than low laser fluence.     

Double pulse laser ablation and plasma: Laser induced breakdown spectroscopy signal enhancement

A review of recent results of the studies of double laser pulse plasma and ablation for laser induced breakdown spectroscopy applications is presented. The double pulse laser induced breakdown spectroscopy configuration was suggested with the aim of overcoming the sensitivity shortcomings of the conventional single pulse laser induced breakdown spectroscopy technique. Several configurations have been suggested for the realization of the double pulse laser induced breakdown spectroscopy technique: collinear, orthogonal pre-spark, orthogonal pre-heating and dual pulse crossed beam modes. In addition, combinations of laser pulses with different wavelengths, different energies and durations were studied, thus providing flexibility in the choice of wavelength, pulse width, energy and pulse sequence. The double pulse laser induced breakdown spectroscopy approach provides a significant enhancement in the intensity of laser induced breakdown spectroscopy emission lines up to two orders of magnitude greater than a conventional single pulse laser induced breakdown spectroscopy. The double pulse technique leads to a better coupling of the laser beam with the plasma plume and target material, thus providing a more temporally effective energy delivery to the plasma and target. The experimental results demonstrate that the maximum effect is obtained at some optimum separation delay time between pulses. The optimum value of the interpulse delay depends on several factors, such as the target material, the energy level of excited states responsible for the emission, and the type of enhancement process considered. Depending on the specified parameter, the enhancement effects were observed on different time scales ranging from the picosecond time level (e.g., ion yield, ablation mass) up to the hundred microsecond level (e.g., increased emission intensity for laser induced breakdown spectroscopy of submerged metal target in water). Several suggestions have been proposed to explain the mechanism of double pulse enhancement.     

Real-time measurements of polychlorinated biphenyls using laser ionization time-of-flight mass spectrometry.

Polychlorinated biphenyls (PCBs) are hazardous compounds for which there are few methods involving real-time measurement. Recently, the development of the pulsed-laser technique has enabled us to measure aromatic hydrocarbons quite rapidly. In particular, the LI-TOFMS (laser ionization time of flight mass spectrometry) technique is expected to be a powerful method for on-line, selective and sensitive measurements. In the context of developing a highly selective and sensitive technique, the effective laser wavelength and pulse duration for laser ionization of 2-4 chlorinated PCBs are considered. Excitation at lambda = 266 nm was found to be substantially more effective than at lambda = 280, 300 or 320 nm. Also, picosecond excitation for PCBs underwent more efficient ionization (by a factor of over 10) and less fragmentation than nanosecond excitation. The achievable sensitivity for trichlorinated biphenyl in a real-time (1 min) measurement using the LI-TOFMS technique was estimated to be in the sub-ppbV range (< 0.01 mg/Nm3).     

Spectroscopy of highly excited vibrational states of HCN in its ground electronic state

An experimental technique based on a scheme of vibrationally mediated photodissociation has been developed and applied to the spectroscopic study of highly excited vibrational states in HCN, with energies between 29,000 and 30,000 cm(-1). The technique consists of four sequential steps: in the first one, a high power laser is used to vibrationally excite the sample to an intermediate state, typically (0,0,4), the nu3 mode being approximately equivalent to the C-H stretching vibration. Then a second laser is used to search for transitions between this intermediate state and highly vibrationally excited states. When one of these transitions is found, HCN molecules are transferred to a highly excited vibrational state. Third, a ultraviolet laser photodissociates the highly excited molecules to produce H and CN radicals in its A 2Pi electronic state. Finally, a fourth laser (probe) detects the presence of the CN(A) photofragments by means of an A-->B-->X laser induced fluorescence scheme. The spectra obtained with this technique, consisting of several rotationally resolved vibrational bands, have been analyzed. The positions and rotational parameters of the states observed are presented and compared with the results of a state-of-the-art variational calculation.     

火焰结构的平面激光诱导荧光技术观测

用平面激光诱导荧光（PLIF）技术测量了烧煤油的酒精喷灯单脉冲激光诱导荧光，由平面荧光图可清晰地看到氢氧基与C2、C3在火焰中的位置，同时，也看到了煤油火焰由发生、发展到熄灭过程中火焰结构的变化；PLIF技术是研究火焰结构的有力工具。     

Determination of Surfactants Using Ion Pair Extraction of Near-infrared Laser Dyes

Abstract

Ionic surfactants and near-infrared laser dyes formed complexes which were extracted into organic solvents as ion pairs. Surfactants were determined spectrophotometrically by measuring the near-infrared absorbance and fluorescence of the ion pair in the organic solvent. Several of the commercially available near infrared dyes have been found suitable for surfactant determination in water using this technique. The excess near-infrared dye coextracted into the organic solvent was determined by blank extractions. The calibration curves were linear within two orders of magnitude of surfactant concentrations. Non-linear calibration curves are obtained for wider concentration range of surfactants. This method using the recently developed near-infrared laser diode intracavity technique was applied to the determination of SDS in water. Lower detection limits and ease of operation are the major advantages of using this new laser diode technique. The extraction efficiency of different solvent systems was evaluated.