氢化物发生—缝管原子捕集—原子吸收法测定钢铁和地质试样中的砷

介绍简易的氢化物发生原子吸收测砷的方法，喷雾器负压将ＫＢＨ５吸入反应器，并将生成的ＡｓＨ３吸入乙炔－空气焰原子化。石英缝管使灵敏度提高３．５倍，方法的检测限为１．８ｎｇ／ｍＬ（５ｍＬ试样）。２０ｎｇ／ｍＬ Ａｓ（Ⅲ）标准液１０次测定的ＲＳＤ为３．８％。本法成功地应用于钢铁和地质标样中微量砷的测定。     

顺序注射-氢化物发生原子吸收法测定砷

通过在气液分离器的液体出口处增置微型电磁阀,延长样品和还原剂NaBH4在气液分离器中的反应时间,实现了单注射泵顺序注射-氢化物发生原子吸收法测定砷。本法自动化程度高,分析速度112次／h,样品消耗量为0．4mL;4μg/L As测定10次的相对标准偏差为2．0％;检出限0．09μg/L。用于标样中砷的测定,结果满意。     

氢化物发生-原子吸收法测定饮用水中的砷、硒

建立了测定饮用水中砷、硒的氢化物发生－原子吸收法，探讨了盐酸、硼氢化钠溶液的浓度以及样品还原处理对测定结果的影响，测定结果的相对标准偏差（n=7)小于3％，回收率为89．1％－110．7％，测定砷的线性范围为0－40ug/L(r=0.9990)，测定硒的线性范围为0－50ug/L(r=0.9990)，砷、硒的检出限分别为1．06，0．78ug/L。     

氢化物发生原子吸收法测定卡托普利

根据卡托普利与醋酸铅反应定量生成沉淀的特点 ,通过用氢化物发生原子吸收法测定沉淀中的铅 ,可间接测定卡托普利的含量。平均回收率 99.8% ,RSD值为 1 .6%     

氧弹燃烧-氢化物发生-原子吸收法测定硫磺中砷

研究了氧弹燃烧、NaOH溶液吸收预处理硫磺样品的方法,优化了HG-AAS法测定砷的最佳条件。     

连续氢化物发生—微波等离子体炬原子发射光谱法测定砷

对连续氢化物发生－微波等离子炬原子履地测定砷进行了研究，对这一方法的分析性能考察结果表明，本法对砷的检出限（３σ）ｎｇ／ｍＬ线性范围达三个数量级，大多数共存离子的干扰很小，对实际样品是一种简便、快速、准确的分析方法。     

氢化物原子吸收分光光度法测定食品中砷

食品样中砷的测定一般用银盐法,然而此法灵敏低操作繁琐,本法用氢化物原子吸收分光光度法测定食品中的砷则操作简便、快速、灵敏度高.方法灵敏度为0.8ng·ml~(-1),检出限为0.5ng·ml~(-1).1 试验部分1.1 仪器与试剂WYX-402型原子吸收分光光度计HCF氢化物发生器T型石英管砷标准溶液:100ng·ml~(-1)混合酸:硝酸+高氯酸(4+1)盐酸溶液:0.5mol·L~(-1)硼氢化钾:5g·L~(-1)还原剂:称取碘化钾15g、抗坏血酸10g溶解于离子水,定容至100ml.     

氢化物发生-原子吸收光谱法测定萤石粉中砷

提出了以氢化物发生-原子吸收光谱法测定萤石粉中砷的方法,研究了酸介质、还原剂、载气流量等因素对测定的影响,并选择出最佳工作条件.砷的检出限为0.052μg·g-1,线性范围为0.10～6.00 μg·L-1,回收率在90.0%～102.0%之间,相对标准偏差为9.8%.     

连续流动氢化物发生—原子吸收光谱法测定地质样品中痕量硒

经试验研究，选定了分析地质样品中痕量硒的测定体系，建立了切实可行的分析方法，该方法不需分离，直接测定，灵敏度高，干扰少，方法测定下限可达０．０２μｇ／ｇ，进行了部分样样分析，结果令人满意。     

氢化物—原子荧光光光谱法同时测定黄铜中的砷与锑

试样用硝酸－硫酸分解,试验了酸度、还原剂浓度以及黄铜中常见元素对测定结果的影响,砷、锑的回收率分别为：９６％～１０９％,９０％～９３％,砷、１锑的检出限分别为０．１９ｎｇ＝ｍＬ、０．３１ｎｇ＝ｍＬ,砷、锑的线性范围分别为０．５～２５０ｎｇ／ｍＬ、０．５～５００ｎｇ／ｍＬ。本法用于黄铜标准样品中的砷、锑。结果与标准值吻合。     

Determination of Inorganic and Total Arsenic in Wines by Hydride Generation Atomic Absorption Spectrometry

A method is described for the determination of inorganic arsenic species and total arsenic in wines by means of hydride generation atomic absorption spectrometry (HGAAS). Simple ethanol evaporation is the only pretreatment procedure proposed for wine samples prior to direct measurement of inorganic arsenic (AsIII) and As(V) species by HGAAS. The total arsenic content is determined after microwave digestion of the wine samples. The optimal parameters for the microwave digestion procedure and the next HGAAS measurement of arsenic are established. The detection limits achieved are 0.1µgL^–1 for inorganic and total arsenic determination. The relative standard deviation for both procedures and for ten independent determinations varied between 8 and 15% for arsenic species in the range of 1–30µgL^–1. The accuracy of the procedure for total arsenic determination was proved by comparative analysis using electrothermal atomic absorption spectrometry.     

Single Laboratory Validation of a Method for the Determination of Total Inorganic Arsenic by Hydride Generation Atomic Absorption Spectrometry

The purpose of this study consists in reporting of single laboratory validation of a method for the determination of total inorganic arsenic by hydride generation atomic absorption spectrometry from natural and residual water samples. Applicability, fitness for purpose, selectivity, and sensitivity were discussed. A calibration study was realized, linear working range (0.4–4 μg·L^?1), detection (0.11 μg·L^?1), and quantification (0.38 μg·L^?1) limits being determined. It was also proven that the method is accurate and precise. Following the bottom-up approach measurement, uncertainty was estimated (method validation data were used).     

氢化物发生辅助雾化火焰原子吸收法测定水中铅

研究了一种提高火焰原子吸收测定铅灵敏度的新方法——氢化物发生辅助雾化的火焰原子吸收法；方法采用硼氢化钠与铅(Ⅳ)在原火焰原子吸收雾化器喷口处反应生成氢化物，以提高火焰原子吸收法的雾化效率；采用重铬酸钾一酒石酸预处理体系，重铬酸钾氧化样品中铅(Ⅱ)为铅(Ⅳ)，酒石酸稳定铅(Ⅳ)的亚稳态化合物；对各种实验参数和干扰情况也进行了研究；方法操作简单、快速，灵敏度比通常的火焰原子吸收法提高了6．8倍；检出限(K=3，n=11)为6．64μg/L，线性范围为0．021～3．2mg／L；测定水样的回收率达94％～99％。     

Hydride Generation Atomic Fluorescence Spectrometric Determination of Ultratrace Arsenic in High Purity Indium Oxide

A simple, sensitive, and interference free method was proposed for the determination of total arsenic in high purity indium oxide by hydride generation atomic fluorescence spectrometry (HG-AFS). Preconcentration was carried out by distillation of volatile arsenic trichloride. Hydrazine sulfate was used as a prereductant to reduce As (V) to As (III). The volatile arsenic trichloride generation was based on the reaction between As (III) and hydrochloric acid, and vapors were absorbed with water. The method provides a linear response range of 2 ng/mL–70 ng/mL, a detection limit of 0.1 ng/mL, a recovery of 96%–113%, and an average relative standard deviation of 2.42%. The method was validated by means of interlaboratory comparative analysis with the proposed method HG-AFS, and the comparison of data by using proposed method HG-AFS and reference methods of ICP-OES and spectrophotometry.     

Advances in On-Line Hydride Generation Atomic Spectrometric Determination of Arsenic

Flow analysis has played a major role in many areas of chemical analysis, making operations more robust and precise. It facilitates experimental studies opening new areas of research. In the field of arsenic research, there are various examples of surveys concerning arsenic determination and its species with the use of flow injection analysis (FIA) and sequential injection analysis (SIA). The increasing concern over the human exposure to arsenic and its species has necessitated the development of rapid, highly sensitive, precise, and accurate analytical methods for its determination in trace levels in environmental and biological samples. This review provides a literature survey on the automatic on-line hydride generation methodologies coupled to atomic spectrometry for determination of inorganic and organic arsenic species, during the last decades. All advances in on-line manifolds are categorized and highlighted. There are several reports of manifolds and setup instrumentation concerning hydride generation including continuous flow analysis (CFA), FIA, SIA, lab-on-valve (LOV), multicommutation flow systems, and hyphenated techniques. On-line preconcentration and pretreatment methodologies coupled with hydride generation such as solid phase extraction, co-precipitation and trapping are also discussed, as they are of particular interest in the development of fully automated methods.     

The Simultaneous Arsenic,Antimony, and Selenium Determination in Water Samples by Batch Hydride Generation Atomic Absorption Spectrometry

The purpose of this paper is to present a procedure for the simultaneous determination of metalloids: arsenic, antimony, and selenium. Hydride generation was provided in a reaction vessel connected with the atomic absorption spectrometer (AAS) in a fast sequential mode. Two different types of water samples were used while developing the application: seawater and groundwater. The methodology of liquid samples analysis was developed with detection limits of 0.05, 0.03, and 0.06 ng · mL^?1 for arsenic, antimony, and selenium, respectively, in 10 mL samples. This methodology was used to determine arsenic, antimony, and selenium in natural water samples.