中国原子光谱发展近况概述SCIEI北大核心CSCD

原子光谱技术作为现代分析检测技术中的一个重要组成部分,在分析领域中占据着举足轻重的地位,而其发展也反映了分析技术的不断改革与创新。综述了中国原子光谱技术近15年来(2000年—2014年)的研究与应用进展。内容涉及原子光谱的多个分支领域,包括原子发射光谱(atomic emission spectrometry,AES),原子吸收光谱(atomic absorption spectrometry,AAS),原子荧光光谱(atomic fluorescence spectrometry,AFS),X射线荧光光谱(X-ray fluorescence spectrometry,XRF)以及原子质谱(atomic mass spectrometry,AMS)五种原子光谱技术,重点关注各技术在检测方法上的创新及其在环境样品、生物样品、食品饮料以及地质材料等相关领域中的应用,并对原子光谱分析中利用到的各种联用技术进行了简要介绍。最后展望了今后我国原子光谱技术的发展方向。     

中国原子光谱发展近况概述

原子光谱技术作为现代分析检测技术中的一个重要组成部分,在分析领域中占据着举足轻重的地位,而其发展也反映了分析技术的不断改革与创新。综述了中国原子光谱技术近15年来(2000年—2014年)的研究与应用进展。内容涉及原子光谱的多个分支领域,包括原子发射光谱(atomic emission spectrometry,AES),原子吸收光谱(atomic absorption spectrometry,AAS),原子荧光光谱(atomic fluorescence spectrometry,AFS),X射线荧光光谱(X-ray fluorescence spectrometry, XRF)以及原子质谱(atomic mass spectrometry,AMS)五种原子光谱技术,重点关注各技术在检测方法上的创新及其在环境样品、生物样品、食品饮料以及地质材料等相关领域中的应用,并对原子光谱分析中利用到的各种联用技术进行了简要介绍。最后展望了今后我国原子光谱技术的发展方向。     

石墨炉原子吸收光谱用于痕量金属元素的测定

石墨炉原子吸收分析法已广泛应用于环境和生物样品中痕量金属元素的分析。然而,方法应用于复杂样品时仍会遇到困难。最近,石墨炉原子吸收分析的研究内容有抑制盐类干扰、防止分析物在灰化过程中的损失及避免碳化物的形成等方面。     

DBD在原子光谱领域内的应用进展

介质阻挡放电因其体积小、结构简单、能耗低、工作温度低、样品解离/激发能力强等显著特点,特别适合于分析仪器的微型化和便携化。目前,基于介质阻挡放电的原子化器或激发光源已成功应用于原子吸收光谱仪、原子荧光光谱仪和原子发射光谱仪中,促进了小型化原子光谱仪器的发展。总结了介质阻挡放电技术在原子光谱领域内的研究进展,着重阐述了介质阻挡放电-原子发射光谱系统在不同进样方式下的应用情况,分析了每种进样方式的优缺点。本文还对介质阻挡放电技术在诱导蒸气发生、固体直接进样方面的新应用方向进行了评述。虽然介质阻挡放电技术已在原子光谱领域内得到广泛的应用,但其反应机理仍然不明确,制约了其后续的拓展研究。     

结合小波分析法与导数光声光谱技术测量弱光谱信号的实验研究

结合导数光声光谱技术与小波分析方法,精确测量了光声光谱中的弱光谱信号.首先利用自己设计的仪器装置实现光声光谱的一阶导数,在此基础上,根据导数光声光谱的数据选择合理的分析小波,将光声光谱信号分解为不同频率信号的叠加,被分解的信号满足线性性质且原信号的峰值信息保持不变,由频率的差异可区分出光声信号和噪声信号,从而提取出光声光谱中的弱光谱信号.结合物理方法与软件方法的分析结果,准确地测量了氙灯的输出光声光谱中3个不明显的弱峰值,位置分别为699.7nm、753.4nm和776.5nm.该方法可以更准确地提取出光声光谱的峰值信息,有效地提高了光声光谱的测量精度,为光声光谱分析法在生物医学及化学分析中的应用提供了一种更精确的分析方法.     

ICP-MS测定自来水中的金属元素

利用电感耦合等离子体质谱仪的高灵敏度、高准确性和多元素同时分析的特点,可以快速精确地测定自来水中的微量金属元素含量。由于自来水样品中的有害金属元素含量比较低,需要高灵敏度的分析方法,所以与其他元素分析技术相比ICP-MS优势明显,在自来水样品分析中已经得到了广泛的应用。本文用电感耦合等离子体质谱法(ICP-MS)和原子吸收分光光度法(AAS)测定自来水中的金属元素,并对中国与日本自来水进行了取样分析和比较。     

流动注射-导数火焰原子吸收光谱测定植物油中的铜、锌

提出了流动注射 导数火焰原子吸收光谱测定植物油中的微量铜和锌的新方法。流动注射进样技术克服了常规火焰原子吸收法耗样量大和基体干扰严重的缺点。导数技术应用于火焰原子吸收可提高方法的灵敏度和信号的选择性。流动注射与导数技术相结合应用于火焰原子吸收成功地测定了植物油中的微量铜和锌。铜和锌的特征浓度分别为 0 0 0 4 0 ,0 0 0 12 μg·mL-1,相对标准偏差在 1 1%～ 5 1%的范围内。     

中国原子光谱技术及应用发展近况

原子光谱（atomic spectrometry,AS）技术作为分析领域一个重要的组成部分,是尖端科学快速发展的助推器。随着国家对高新技术的愈加重视,国内的分析检测技术也在飞速发展,原子光谱技术作的发展则成为了极其重要的推动力。对中国原子光谱近4年（2015年-2018年）的研究成果与应用进展做了一个综述,内容主要分为六大部分：原子发射光谱（atomic emission spectrometry, AES）包括电感耦合等离子体发射光谱（inductively coupled plasma optical emission spectrometry, ICP-OES）,辉光放电发射光谱（glow discharge optical emission spectrometry, GD-OES）,介质阻挡放电发射光谱（dielectric barrier discharge optical emission spectrometry, DBD-OES）和激光诱导击穿光谱（laser induced breakdown spectrometry, LIBS）;原子吸收光谱（atomic absorption spectrometry, AAS）包括火焰原子化吸收光谱（flame atomic absorption spectrometry, FAAS）,石墨炉原子化吸收光谱（graphite furnace atomic absorption spectrometry, GFAAS）和氢化物发生原子吸收光谱（hydride generation atomic absorption spectrometry, HGAAS）;原子荧光光谱（atomic fluorescence spectrometry, AFS）;X射线荧光光谱（X-ray fluorescence spectrometry, XRF）;元素质谱（elemental mass spectrometry, EMS）包括电感耦合等离子体质谱（inductively coupled plasma mass spectrometry, ICP-MS）,辉光放电质谱（glow discharge mass spectrometry, GDMS）,激光电离源质谱（laser ionization mass spectrometry, LIMS）和原子探针层析成像（atom probe tomography, APT）;原子光谱分析的联用技术。主要关注了各个技术及各种联用技术在仪器设备、检测方法、检测性能上的突破和创新,并简要介绍它们在电子、冶金、地质、环境、制药、食品、生命科学等多种领域中的应用。     

原子光谱分析的进展及其应用

文章综述了原子光谱领域分析仪器及分析方法的最新研究进展;例如原子吸收光谱(AAS)、原子发射光谱(AES)、原子荧光光谱(AFS)、激光诱导击穿光谱(LIBS)以及原子质谱(AMS)等,重点关注在食品、医药及其相关领域中的应用。近年出现的芯片实验室和微等离子体,促进了原子分析仪器的微型化发展,而激光及其联用技术在形态分析中的应用仍颇为流行。     

悬浮液进样石墨炉原子吸收光谱分析进展

悬浮液石墨炉原子吸收光谱分析结合了固体和液体进样方式的显著优势,是一种相对成熟的技术,并已作为常规分析方法广泛应用于有机和无机复杂基体中微、痕量金属元素的分析测定。文章结合最近10年来所取得的新进展进行综述,着重介绍和评论了悬浮液的制备(介质、稳定剂、质量体积比、粒径、均匀化体系)、基体改进剂、背景校正、方法校正及其分析的精密度等,并对悬浮液石墨炉原子吸收光谱分析的发展趋势进行了展望。全文共引用国内外文献80篇。     

The Application of Photon Counting as a Detection System in Atomic Fluorescence and Emission Spectrometry

Despite the profusion of literature associated with analytical atomic spectrometric techniques, very little has been reported concerning the development of detector systems. This is particularly surprising in view of the current trend in atomic spectrometry towards the use of non-flame atom reservoirs. These devices frequently produce weak transient signals and dc level detector systems designed for steady state measurements are in consequence often unsatisfactory. High speed recorders may be used with success providing the total response time of the various electronic components is comparable with or preferably less than that of the signal duration and only in such instances will precise measurement of the signal be achieved (1,2). The use of absolute integration techniques are obvious for this type of measurement, although their application has not been particularly forthcoming to date. Photon counting would seem to have many advantages for such purposes, although with the exception of the more general studies of Morton (3) and Malmstadt and co-workers (4) it has received so far little consideration. Indeed its use as a detection system in analytical atomic fluorescence and emission spectrometry has yet to be reported.     

增感效应导数火焰原子吸收光谱测定金属铜中微量铅

本文提出了增感效应导数火焰原子吸收光谱测定金属洞中微量铅的新方法，研究了基体铜对铜的增感效果，导数技术与增感效应相结合可使火焰原子吸收光谱的灵敏度提高１７倍，用本法测定金属铜中的微量铅取得了满意效果     

Molybdenum,Platinum, and Tantalum Metal Atomizers or Vaporizers in Analytical Atomic Spectrometry

Abstract

The application of metal (tantalum, molybdenum, and platinum) devices in analytical atomic spectrometry is reviewed in this article. These metal devices have been employed in various analytical atomic spectrometric techniques for more than three decades, mainly as electrothermal atomizers or electrothermal vaporizers, in various physical shapes, such as tubes, platforms, loops, and wires (or coils/filaments). Their application spans from atomic absorption spectrometry (AAS), atomic emission spectrometry (AES) atomic fluorescence spectrometry (AFS), inductively coupled plasma atomic emission spectrometry (ICP‐AES) to inductively coupled plasma mass spectrometry (ICP‐MS). The analytical figures of merit and the practical applications reported for these metal devices are reviewed, and the atomization mechanism on these metal atomizers is briefly summarized, too. In addition, other applications of the metal devices are discussed, including analyte preconcentration by electrodeposition and sequential metal vapor elution analysis (SMVEA). Furthermore, the application of these metals in graphite furnaces encompasses the schemes with the metals in the form of furnace linings, platforms, or impregnated salts.     

Sample Preparation for the Determination of Metals in Food Samples Using Spectroanalytical Methods—A Review

Abstract

The present article gives an overview of recent publications and modern techniques of sample preparation for food analysis employing atomic and inorganic mass spectrometric techniques, such as flame atomic absorption spectrometry, chemical vapor generation atomic absorption and atomic fluorescence spectrometry, graphite furnace atomic absorption spectrometry, inductively coupled plasma optical emission spectrometry, and inductively coupled plasma mass spectrometry. Among the most frequently applied sample preparation techniques for food analysis are dry ashing, usually with the addition of an ashing aid, and acid digestion, preferably with the assistance of microwave energy. Slurry preparation, particularly with the assistance of ultrasound, is increasingly used to reduce acid consumption and sample preparation time. Direct analysis of solid samples is gaining importance in the field of food analysis as it offers the highest sensitivity, avoids the use of acids and other aggressive reagents, makes possible the analysis of micro‐samples, and can be applied for fast screening analysis, e.g., of fresh meat.     

悬浮体制样石墨炉原子吸收光谱法直接测定琥珀中微量镉

报道了以硝酸钯为基体改进剂,采用悬浮体制样石墨炉原子吸收光谱法直接测定琥珀中微量Cd的方法。研究了悬浮剂、试样粒度、基体改进剂、灰化/原子化温度和共存金属离子对分析信号的影响。在优化实验条件下,方法的检出限为9.4 ng·g-1,相对标准偏差(RSD)为6.1%。     

Determination of Trace Elements in Vegetable Oils and Biodiesel by Atomic Spectrometric Techniques—A Review

Abstract

The determination of trace elements in edible oils and biodiesel using atomic spectrometric methods is reviewed. Problems related to sample pretreatment for appropriate sample introduction and calibration are addressed as well as the strategies to overcome them. Recent trends aimed at simplifying sample manipulation are presented. The applications and scope of atomic absorption spectrometry (AAS), flame optical emission spectrometry (F-OES), inductively coupled plasma–optical emission spectrometry (ICP-OES), and inductively coupled plasma–mass spectrometry (ICP-MS) techniques for the determination of trace metals in edible oils and biodiesel are discussed, as well as some current instrumental new developments.     

Interfacing Microfluidic Handling with Spectroscopic Detection for Real‐Life Applications via the Lab‐on‐Valve Platform: A Review

Abstract

One of the current needs within the analytical spectrometric community is the development of straightforward and cost‐effective, yet rugged, sample processing procedures aimed at precluding both spectroscopic and nonspectroscopic matrix interferences while fostering concomitant sample enrichment. Illustrated via selected representative examples, this review presents and discusses the current state of the art in implementing miniaturised and automated sample treatments for environmental and biochemical assays via microfluidic systems exploiting the lab‐on‐valve (LOV) platform in hyphenation with syringe pump propelling devices as a front end to a plethora of spectroscopic detection schemes including ultraviolet‐visible (UV‐Vis) spectrometry, spectrofluorimetry, chemiluminescence, atomic absorption spectrometry (AAS), atomic flourescence spectrometry (AFS), and inductively coupled plasma‐atomic emission spectrometry/mass spectrometry (ICP‐AES/MS). In contrast to lab‐on‐a‐chip units, the versatile configuration of the micromachined LOV readily facilitates the implementation of on‐line unit operations at will encompassing not merely the introduction of minute, well‐defined volumes of sample followed by chemical derivatization, but the potential for accommodation of solid‐phase extraction, hydride/vapor generation, precipitation/coprecipitation, and bead injection protocols with no need for chip redesign.     

Atomic spectrometry and atomic mass spectrometry in bioanalytical chemistry

Abstract

Atomic spectrometry and atomic mass spectrometric (MS) techniques have been playing crucial roles in the field of biosciences. They detect elements with relatively high sensitivities and are thus applicable to a wide range of analytical targets. In the past decade, determination of bio-relevant metallic elements continues to be of interest, while particularly noteworthy are methods developed for small molecules, peptides, proteins, nucleic acids and even cells that well exploited the bio-analytical strengths of atomic spectrometry and atomic MS, either in a direct or indirect manner. Quantitation, as well as speciation and imaging analyses are all involved. The present review aims to assimilate recent advances in bio-analysis utilizing atomic spectrometry and atomic MS, primarily covering the period of 2013–2018, in an attempt to provide readers insight into the developing trends of this research frontier. Followed by concluding remarks and perspectives, the applications are divided into the following four catalogs: (i) toxicologically important metal-containing species, with an emphasis on quantitative and imaging analysis; (ii) quantitation of biomolecules using naturally occurring heteroatoms; (iii) exogenous metal ion or nanoparticle tagging-based strategies in bioassays; and (iv) label-free detection of biomolecules.     

Exploration of Displacement Reaction/Sorption Strategies in Spectrometric Analysis

Abstract

Displacement reactions are very popular in nature, ranging from texbook knowledge of the Zn-CuSO₄ system to modern functional nucleic acid–involved metal ion displacement. Though synthetic chemistry harvests a lot from displacement reactions, analytical chemistry benefits greatly from various displacement reaction strategies, such as sensitivity improvement. In particular, the use of indicator displacement assay for new sensor development is of great interest worldwide. In this review, we summarize the advances in utilization of displacement reactions for improved spectrometric analysis. The main contents include displacement-based preconcentration schemes for trace metal analysis by analytical atomic spectrometry, indicator displacement assays focusing on the use of advanced nanomaterials, and displacement immunoassays using spectrometric measurements, with 117 references.