微波消解-双道原子荧光法同时测定家禽肝脏中硒和碲

建立了微波消解样品,双道原子荧光光谱法同时测定家禽肝脏中的Se和Te。优化了仪器工作参数、反应体系及消解条件,考察了Cr3+,Cu2+,Pb2+,Co2+,Zn2+,Ni2+,As3+,Sb3+等8种共存离子的干扰。在选定的最佳实验条件下,Se和Te的方法检出限分别为0.11μg/L和0.077μg/L,日间、日内RSD均小于5%;样品中Se,Te的加标回收率分别在93.2%~104.7%及90.8%~101.3%之间。方法适合于家禽肝脏中非金属元素含量的测定。     

顺序注射氢化物发生-原子荧光光谱法同时测定硒和砷的研究

建立了一种顺序注射氢化物发生-原子荧光光谱法测定试样中Se和As的方法,同时讨论了共存离子的干扰情况.在最佳实验条件下,Se和As的检出限分别为0.16和0.095 μg/L,加标回收率为92.4%～104.7%.     

离子交换色谱-氢化物发生双道原子荧光法同时测定砷和硒形态

建立了离子交换色谱-氢化物发生双道原子荧光联用同时测定4种As形态和3种Se形态的方法,并优化了各种实验参数。采用PRP-X100阴离子交换分析柱可以在10min内同时分离、检测As和Se形态。在8%HCl和1.5%(m/V)KBH4的氢化物反应条件下,进样量100μL,各形态的检出限为:As(Ⅲ)0.2μg/L、DMA0.3μg/L、MMA0.2μg/L、As(Ⅴ)0.3μg/L、SeCys0.6μg/L、Se(Ⅳ)0.5μg/L、SeMet3μg/L。当各As形态浓度为100μg/L、各Se形态浓度为200μg/L,各形态的精密度RSD(n=7)均小于5%。当各As形态浓度范围为5～100μg/L、SeCys和Se(Ⅳ)浓度范围为10～200μg/L、SeMet浓度范围为50～200μg/L时,各形态均可得到良好的线性关系,线性相关系数均大于0.9992。用建立的方法测定了富硒营养品中的As和Se形态,加标回收率在91%～115%之间。     

垃圾渗滤液中 As和 Hg的流动注射蒸气发生非色散原子荧光光谱法测定

建立了垃圾渗滤液中As和Hg的流动注射蒸气发生－非色散原子荧光光谱的测定方法。在低温下采用硝酸－过氧化氢体系消化处理样品;硫脲－抗坏血酸将As(V）还原后测定样品中的总As;Hg的测定用Hg蒸气发生原子荧光光谱法。对测量条件进行了优化,在优化实验条件下测得As和Hg的检出限分别为0．08和0．007μg/L,10次测定的相对标准偏差分别为0．48％和0．85％（对8．0μg/L As和1．0μg/L Hg标准溶液）。共存的NaCI、MgCI2、CaCI2、Na2SO4、NaF以及微量共存金属离子（Cd、Se、Zn、Pb、Cu、Fe、Mn、AI）对As和Hg的测定没有干扰。用标准校正曲线和标准加入法对样品测定结果进行了比较,实验结果表明二者吻合较好。     

Carius管密封溶样-等离子体质谱法测定环境样品中镓、锗、砷、硒、镉、锡、锑、碲、汞、铅和铋

利用Carius管密封溶样技术,建立了王水分解-等离子体质谱直接测定环境样品中Ga,Ge,As,Se,Cd,Sn,Sb,Te,Hg,Pb和Bi的分析方法。在190℃下加热分解样品,稀释后可直接进行元素的分析测定。仪器测量时,乙醇不仅对As,Se和Te的检测信号有较明显的增敏作用,而且对复合离子ArCl+的形成还有一定的抑制作用。实验发现,3%乙醇增敏效果最好,分析信号强度可提高2～4倍。基于样品流程空白,所得方法检出限(3σ,DF=1000)为0.001μg/g(Cd)～0.281μg/g(Pb)。本方法应用于一系列土壤和水系沉积物国家标准物质,所得分析结果与推荐值相吻合,方法精度(RSD,n=3)优于5%。     

电化学氢化物发生原子荧光法同时测定砷和锑

采用电化学氢化物发生与原子荧光联用技术，同时测定了样品中的As和Sb含量。对各种实验参数和干扰情况进行了详细研究。As在0～500μg/L，sb在0～300μg/L之间均有良好的线性关系；相对标准偏差(RSD)(10μg/L，n=11)分别是3．7％和1．8％；检出限分别为0．14μg/L和0．20μg/L。     

微波辅助萃取-液质联用技术测底泥砷、硒的化学形态

建立了用反相离子对色谱和电感耦合等离子体质谱的联用技术同时测定As（Ⅲ）、 As（Ⅴ）、 MMA、 DMA、 Se（Ⅳ）、 Se（Ⅵ）、 SeMet和SeCys的砷、硒化学形态分析方法. 分别从流动相pH值、离子对试剂的浓度、甲醇量和流速4个方面进行了分离测定条件的优化. 利用碰撞池技术（CCT）较好地解决了^40Ar^35Cl^＋复合离子对^75As的干扰, 并使^80Se的测定成为可能, 有效地提高了灵敏度. 将该方法应用于上海市苏州河底泥样品的微波辅助萃取液的形态分析中, 砷和硒的检出限分别达到0.4～1.3 和0.5～1.9 μg/L.     

微波消解/ICP-MS法测定食品级润滑油(脂)中的锑、砷、镉、铅、汞、硒

建立了微波消解样品,ICP-MS同时测定食品级润滑油(脂)中Pb,Cd,As,Se,Sb,Hg 6种微量元素的分析方法。通过优化实验条件,方法测试食品级润滑油(脂)样品中6种微量元素的检出限在0.001~0.020μg/g之间,Pb,Cd,As,Se,Sb在5.00~100.00μg/L范围内呈现良好的线性关系,Hg在0.50~10.0μg/L范围内呈现良好的线性关系,线性相关系数均大于0.999,回收率在93.3%~116%之间,相对标准偏差(n=10)在2.3%~4.2%之间。方法能够满足食品级润滑油(脂)中微量有毒有害元素的定量测定要求。     

树脂分离-氢化物发生-原子荧光光谱法测定食品中无机砷、一甲基胂和二甲基胂

建立了用阴离子交换树脂分离-氢化物发生原子荧光光谱法测定食品中无机砷、一甲基胂和二甲基胂的方法.分别从样品上样条件及二甲基胂、一甲基胂、 As(Ⅲ)和As(Ⅴ)分离条件进行了优化.研究了树脂处理程序对分离的影响,并探讨了共存离子对测定砷的干扰和消除的方法.对方法的适用范围做了研究.本方法具有操作简便、快速、灵敏度高等优点.检出限(以砷计)分别为: 无机砷0.34 μg/L,一甲基胂0.57 μg/L,二甲基胂0.46 μg/L.     

双阳极电化学氢化物发生原子荧光光谱法测定砷

用双阳极电化学氢化物发生原子荧光光谱法测定砷,减少了化学试剂使用给环境带来的污染。在相同条件下,双阳极电化学氢化物发生效率为化学法的99.0%~101.6%。对各种实验参数和干扰情况进行了详细研究。在选定的实验条件下,100μL进样量的As(Ⅲ)线性范围为0~120μg/L;检出限为0.64μg/L(信噪比S/N=3);60μg/L的As(Ⅲ)标准溶液平行进样13次,荧光信号面积的相对标准偏差(RSD)为2.02%。用本法测得GBW07406号标准土壤样品中As含量为(205.2±1.4)μg/g与标准值(220±21)μg/g一致,仔猪饲料样品的加标回收率为97.0%~103.0%。本法灵敏度高、重现性好、结果准确。     

Highly sensitive sensory materials for fluoride ions based on the dithieno[3,2-b:2',3'-d]phosphole system

[structure: see text]. The newly developed functionalization of an unsubstituted dithieno[3,2-b:2',3'-d]phosphole at the 5,5'-positions gives access to bis(pinacoleboryl) species that can be utilized as sensory materials for fluoride ions. The fluoride-triggered response of the air- and moisture-stable boryl-functionalized dithienophosphole oxide manifests itself in the generation of a new fluorescence emission that can be detected at very low analyte concentrations (ppm) or even with the naked eye upon irradiation with UV light (366 nm).     

Reduction of chloride matrix effect using silver oxide as a precipitating reagent for the determination of trace anions in chloride-rich samples via ion chromatography

A new method was developed for the determination of trace anions in chloride-rich samples via ion chromatography by reducing the concentration of chloride ions using silver oxide as a precipitating reagent. In this method the sample pretreatment was started with the addition of silver oxide powder followed by 8 min of stirring and 2 min of centrifugation at a speed of 1500 rpm. The supernatant was diluted with a 1:10 ratio using deionized water and filtered with a 0.22 microm NC filter. All the samples were analyzed in a Dionex ICS-2500 system with an ED50 electrochemical detector in conductivity mode. On the basis of Dionex IonPac AG18 (50 mm x 2 mm) and AS18 (250 mm x 2 mm) columns, 25 AL sample filtrate was eluted isocratically with a mobile phase of 32 mmol/L NaOH at a flow rate of 0.25 mL/ min and each eluted analyte was detected after postcolumn suppression via a Dionex anion suppressor ULTRA II (2 mm). With this method most of the common anions at mg/kg level in chloride-rich samples can be accurately quantified. By controlling the equivalent weight ratio of silver oxide to chloride in sample solutions and the time of pretreatment, the free silver and chloride ions in the sample solution are optimized such that most coexisting common anions can be determined simultaneously.     

Optically Transparent Electrodes Modified with Sulfide Ion‐Covered CdS Quantum Dots for Sensitive Photoelectrochemical Detection of Sulfhydryl‐Containing Compounds

A sensitive and selective photoelectrochemical sensor has been developed. Negatively charged, citrate‐capped CdS quantum dots (QDs) are assembled layer‐by‐layer onto indium tin oxide (ITO) electrodes precoated with positively charged poly(diallyldimethylammonium chloride). By exposing the modified photoelectrochemical electrodes to a Na₂S solution, QDs can be covered with excess S^2? ions. The weakly bound S^2? ions are easily replaceable with a sulphydryl‐containing analyte, and the photocurrent decrease is proportional to the analyte concentration. The detection limit is 0.4 nM for cysteine with a linear range of 1.0–100.0 nM. The level of cysteine in human serum samples has been quantified.     

A novel octadecylsilane functionalized graphene oxide/silica composite stationary phase for high performance liquid chromatography

An octadecylsilane functionalized graphene oxide/silica stationary phase was fabricated by assembling graphene oxide onto the silica particles through an amide bond and subsequent immobilization of octadecylsilane. The chromatographic properties of the stationary phase were investigated by reversed-phase chromatography with alkylbenzenes, polycyclic aromatic hydrocarbons, amines, and phenolic compounds as the analytes. All the compounds achieved good separation on the column. The comparison between a C18 commercial column and the new stationary phase indicated that the existence of π-electron system of graphene oxide allows π-π interaction between analyte and octadecylsilane functionalized graphene oxide/silica stationary phase except for hydrophobic interaction, while only hydrophobic interaction presented between analyte and C18 commercial column. This suggests that some analytes can be better separated on the octadecylsilane functionalized graphene oxide/silica column.     

Determination of vanadium by reaction cell inductively coupled plasma mass spectrometry

Recent advances in inductively coupled plasma mass spectrometry (ICP-MS) have included the addition of interference reduction technologies, such as collision and reaction cells, to improve its detection capability for certain elements that suffer from polyatomic interferences. The principle behind reaction cell (RC)-ICP-MS is to remove a particular polyatomic interference by dissociation or formation of a different polyatomic species that no longer interferes with the analyte of interest. However, some interferences cannot be removed by commonly reported reaction gases, such as hydrogen, oxygen, or methane, necessitating using more reactive and hazardous gases, such as ammonia. The current study investigates oxygen as a reaction gas in RC-ICP-MS to specifically react with vanadium analyte ions, rather than the interferents, to produce a polyatomic analyte species and thereby provide a way to analyze for vanadium in complex environmental matrices. The technique has been tested on a series of river water, tap water, and synthetic laboratory samples, and shown to be successful in vanadium analyses in high chloride and sulfate matrices. The zinc isobaric interference on the new vanadium oxide analyte at m/z 67 is also investigated, and can be corrected by using a standard mathematical correction equation. The results of this study further increase the utility of RC-ICP-MS analytical techniques for complex environmental matrices.     

Use of zwitterionic micelles in the eluent: a new approach for ion chromatographic (IC) analysis of ions in biological fluids with direct sample injection

The problem of column performance degradation due to irreversible binding of proteins encountered in ion chromatographic (IC) analysis of ions in protein-containing samples was overcome by using zwitterionic micelles (e.g., Zwittergent-3-14) as a portion of the eluent. A zwitterionic micellar eluent showed high ability for solubilization of proteins, and, hence, the protein-containing samples could be analyzed without need for deproteinization. On the other hand, the zwitterionic micelle was insensitive to conductivity but interacted with the analyte ions, due mainly to its unique configuration of charges (namely, the zwitterionic micelle containing both positively and negatively charged groups but carrying no net charge). Using a zwitterionic micellar eluent, the analyte ions could be detected selectively and sensitively, and moreover, the selectivity for the analyte ions was unique. A conventional anion-exchange column conditioned with a Zwittergent-3-14 micellar eluent was applied for the analysis of real biological samples (serum and urine) with direct sample injection. The results of the successful detection of inorganic anions (Cl-, SO4(2-), NO2-, Br-, and NO3-) have demonstrated the usefulness of this new IC approach for the analysis of biological samples.     

Extractive chromatographic separation and inductively coupled plasma atomic emission spectrometric determination of trace impurities in high purity europium oxide

An easily applicable separation method has been developed for the accurate and simultaneous determination of trace amounts of Al, Ca, Co, Cr, Cu, Mg, Mn, Ni, Pb and Zn in high purity europium oxide by inductively coupled plasma atomic emission spectrometry (ICP-AES) combined with extraction chromatography. Spectral interferences and europium matrix effects were examined. The chromatographic separation procedure was carried out with a di-(2-ethylhexyl) phosphoric acid (HDEHP)-Levextrel resin as the stationary phase, which retained the matrix europium, and dilute nitric acid as the mobile phase, which eluted the analyte of interest. The effect of nitric acid concentration on the adsorption of europium and the analyte ions on the resin, the eluting behaviour of these elements on the chromatographic column, and the capacity of the resin for europium oxide were investigated. The quantitative limits for determination (10 sigma), based on a 0.5-g amount of europium oxide, are between 0.36 microg/g for Mn and 6.4 microg/g for Pb. The method was applied to two spiked samples and a high purity europium oxide certified reference material. Results were obtained for recoveries of 93.2-112% and precision of 4-13%, expressed as the relative standard deviation and excellent agreement with the certified value with a relative error of <4%.     

Adduct-ion formation in trapped ion mobility spectrometry as a potential tool for studying molecular structures and conformations

Recent developments in the field of ion mobility spectrometry provide new possibilities to explore and understand gas-phase ion chemistry. In this study, hyphenated trapped ion mobility spectrometry-mass spectrometry (TIMS-MS) was applied to investigate analyte ion mobility as function of adduct ion formation for twelve pharmaceutically relevant molecules, and for tetrahydrocannabinol (THC) and its isomer cannabidiol (CBD). Samples were introduced by direct infusion and ions were generated with positive electrospray ionization (ESI+) observing protonated and sodiated ions. Measurements were performed with and without addition of cesium-, lithium-, silver- and sodium ions to the samples. For the tested compounds, metal adduct ions with the same m/z but with different mobility and collision cross section (CCSs) were observed, indicating different molecular conformations. Formation of analyte dimers was also observed, which could be associated with molecular geometry of the compounds. By optimizing the range and speed of the electric field gradient and ramp, respectively, the separation of THC and CBD was achieved by employing the adduct formation. This study demonstrates that the favorable resolution of TIMS combined with the ability to detect weakly bound counter ions is a valuable means for rapid detection, separation and structural assignment of molecular isomers and analyte conformations.     

Coprecipitation of heavy metals with erbium hydroxide for their flame atomic absorption spectrometric determinations in environmental samples

Trace amounts of copper, manganese, cobalt, chromium, iron and lead were quantitatively coprecipitated with erbium hydroxide on 0.05 M NaOH medium. The coprecipitant could be easily dissolved with 1 M nitric acid. The presence of up to 15 g/l of erbium ions did not interfere with the atomic absorption spectrometric determination of analyte ions. The recovery values for analyte ions were higher than 95%. The concentration factor was 25-fold. Coprecipitation parameters including reagent amounts and matrix effects are discussed. The relative standard deviations of the determinations were below 9%. The time required for the coprecipitation was about 30 min. The proposed method was successfully applied for the determination of trace amounts of analyte ions in urine, soil and sediment, natural water samples.     

Solid state chemical ionization for characterization of organic compounds by laser mass spectrometry

A new technique involving the addition of a compound to the analyte to serve as a source of "reagent" ions has been developed for negative-ion laser mass spectrometry. This "solid state chemical ionization" leads to ions characteristic of the analyte, owing to ion-molecule reactions between the "reagent" ion and the neutral analyte in the laser-generated plume. Polycyclic aromatic hydrocarbons show formation of an ion corresponding to (M + O - H)(-) in their negative-ion laser mass spectra when mixed with compounds such as sym-trinitrobenzene, sodium nitrate and sodium peroxide. NO(-)(2), O(-), and O(-)(2) serve as "reagent" ions in these compounds. Formation of (M + Cl)(-) is seen in the laser mass spectra of glycosides mixed with hexachlorobenzene. Chloride serves as the "reagent" ion in this case.