BUNSEKI KAGAKU Volume 52, Issue 5

Measurement of distribution of rare earth elements in Arima-type springs using preconcentration with chelating resin/ICP-MS

Rare earth elements (REEs) in Arima-type spring waters were detemined by ICP-MS after pre-concentration with a chelating resin. Our previously reported method was improved by washing the chelating resin with 5 M HCl over night and then removing the mass interference of Ba to Eu-151. The concentrations of REEs in a hot spring of high Cl content are relatively low compared with a low temperature spring of high Cl and CO₂ contents. The correlation of all the REEs concentration, except for the Eu and CO₂ concentration, were found in Arima spring water samples. Thus the carbonate species plays an important role in the REEs contents in these Arima spring water samples. From the chondrite pattern of the REEs, a positive Eu anomaly was observed in all hot spring samples of high Cl and Fe contents in the Arima region. Also the concentration of Eu was correlated with the K concentration in the Arima spring water samples. Eu in spring water was stimulated to be dissociate into the Eu²⁺ ion from the feldspa of wall-rock by a hot water/rock interaction at reduction situation.

The validity of linearity of the calibration line in the determination of anions by ion chromatography with suppressed conductivity detection

The linearity of the regression line for the calibration in anion determination by ion chromatography with a suppressed conductivity detector was studied both theoretically and experimentally. The relationships between the peak area and the concentration of standard solutions were obtained by equilibrium calculations for fluoride, chloride, nitrate and sulphate ions. Theoretical calculations assuming that the non-linearity of the calibration line can be attributed to a shift of the acid-base equilibrium of the solute and eluent ions are consistent with experimental data. Generally, the calibration line is not linear for the anions of a weak acid, such as fluoride ion. Some eluents, such as carbonate salt, give a curved regression line for any solute ions. For a high-precision calibration, the linear regression should be limited to a narrow concentration range because of the non-homogeneous precision of the conductivity measurement. The high order of the regression formula, if necessary, should be adjusted to the data group of the homogeneous precision. Numerical examples of the linear calibration range are shown for fluoride, chloride, nitrate and sulfate ions.

Analysis of alcohols by superheated water chromatography with flame ionization detection

A method for the superheated water chromatography (SWC)-flame ionization detection (FID) of alcohols was developed. An FID system was connected to an SWC system by splitting the mobile phase of the SWC system and then introducing it into the FID system via a fused-silica capillary tube. The FID conditions (the position of the end of the capillary tube in the FID system, flow rate of hydrogen gas, and flow rate of helium makeup gas) were optimized so as to obtain a stable and sensitive detection of alcohols; the detection limits (S/N=3) of methanol, ethanol, 1-propanol, 1-butanol, and 1-pentanol were in the range of 26∼57 ng (as injected amounts into the SWC system) under the optimized conditions. The retention of alcohols in SWC decreased with an elevation in the column temperature as well as a decrease in the mobile-phase pressure. The retention mechanism was characterized using a thermodynamic theory that has been used for describing retention in conventional high-performance liquid chromatography. The application of the present method to determination of ethanol in wine samples was also demonstrated, in which the observed values were comparable to those obtained by gas chromatography/mass spectrometry.

Determination of glycosylated albumin using surface plasmon resonance sensor

The determination of glycosylated albumin (GA) based on an SPR apparatus was performed using the bond formation of GA with boronic acid functional groups on a sensor chip. In order to develop a sensor chip that can reduce non-specific adsorption, the surfaces of gold-evaporated chips were chemically modified by forming self-assembled monolayers (SAMs) of five kinds of thiol compounds. It was confirmed that the sensor chip modified with an ethylene glycol (EG) terminated SAM showed the best results for reducing non-specific adsorption among the examined SAMs. It was found that the sensor chip can reduce the adsorption of proteins of different molecular weights and isoelectric points in serum. Based on these results, the ratio of alkyl thiols having EG and carboxylic acid terminals was optimized in order to prepare a new SPR sensor chip that can immobilize the sensing molecules while preventing non-specific adsorption. In this study, 4-aminophenyl boronic acid was fixed through amido bond formation on a mixed SAM sensor chip while aiming at the quantification of diol compounds. The SPR sensor using this sensing chip could determine GA, which is an example of a sugar-protein, in the concentration range of 7.5∼20% (total amount of albumin).

Reduction of nitrate to nitrite with cadmium metal

The reduction of nitrate to nitrite by using cadmium coated with copper in a reductor column has been widely used on the determination of nitrate. The effects of the flow rate, pH and types of cadmium on the reduction have been investigated. However, the function of copper coated on cadmium has still not been elucidated. In this study, the reduction of nitrate by using cadmium without copper was investigated. Cadmium without copper reduced nitrate to nitrite the same way as cadmium coated with copper, if copper ion was added to a sample solution above 10 mg/l. It was presumed that the reduction of nitrate was affected by the copper ion in the sample solution, rather than copper coated on the cadmium. The effects of chloride ion and silicate on the reduction were smaller than that of cadmium coated with copper.

Determination of trace-elements in certified reference materials of high-purity aluminum by instrumental neutron-activation analysis

Multi-elements in JAC0021, JAC0022 and JAC0023 certified reference materials of high-purity aluminum prepared by the Japan Society for Analytical Chemistry (JSAC) were determined by instrumental neutron-activation analysis (INAA). Four or five aliquots of each sample (ca. 27∼1018 mg) and comparative standards were irradiated for a short time (10 s) at a thermal neutron flux of 1.5×10¹² n cm⁻² s⁻¹ (pneumatic transfer) and for a long time (6 h) at a thermal neutron flux of 3.7×10¹² n cm⁻² s⁻¹ (central thimble) in the Rikkyo University Research Reactor (TRIGA Mark-II, 100 kW). The irradiated samples were measured by conventional γ-ray spectrometry using a coaxial Ge detector, and by anti-coincidence and coincidence γ-ray spectrometry with a coaxial Ge detector and a well-type NaI(Tl) detector. The concentrations of 21 elements in JAC0021, 20 elements in JAC0022 and 11 elements in JAC0023 were determined by these methods.

The feature extraction of water-quality data by using classification and regression trees

Water-quality data of rivers, for example, COD and BOD are important indices for environmental conservation. Whether we can distinguish between the sampling positions or the fiscal year, the sampling time of the water are depend on the way of characterizing the sampling positions or time of the water. We focused our attentions to one of the decision trees, the classification and the regressions trees (CART), because we should have clear splitting rules between the sampling positions or the sampling fiscal years. As a result of using CART, we found that classification between the upper, middle and lower area of Tama river could be completely done based on the conductivity and the chlorine ion. Furthermore, from the splitting rules between the water-quality data of fiscal year ’97, ’98 and ’99, the important point concerning the purification of Tama river’s water-quality, would be considerable reduction of the nitrogen-related chemical species (Total nitrogen, NH₄, NO₂, NO₃). CART should be a useful method for finding the meanings of classifying or the splitting rules of the complicated analytical data or environment data, which have recently increased in number.

Aqueous two-phase extraction of Au(III) and Pd(II)

An aqueous two-phase system, prepared by mixing a tetrabutylammonium bromide(TBAB) solution and Na₂SO₄, was proposed for the extraction of Au(III) and Pd(II) prior to atomic absorption spectrophotometric(AAS) determination. An aqueous two-phase system was obtained as follows: to a 1 ml sample solution containing Au(III) and Pd(II), 3.0 ml of 1.0 mol l⁻¹ TBAB aqueous solution and 1.0 ml of a buffer solution (pH 4) were added and diluted with water to 6.0 ml. Then, 1.8 g of Na₂SO₄ was added to this solution and the mixture was shaken for about 1 min. After complete phase separation was performed, a 0.5 ml aliquot was taken from the upper phase and then diluted with 10 ml of water for AAS determinations of Au(III) and Pd(II). The Au(II) and Pd(II) were quantitatively extracted into the upper phase in the pH range from 1 to 6.5. The proposed method was applied for the determination of Au(III) and Pd(II) in a plating solution. The mean recoveries were 104 and 99% for Au(III) and Pd(II), respectively.

Dissolution of Ir-based alloys including transition metals with sodium peroxide

It is well known that Ir is a chemically stable element that is difficult to dissolve, even in a strong acid. Furthermore, when transition metals are added to it, Ir becomes more difficult to dissolve in acid. To solve this problem, we tried to dissolve Ir-Nb, Ir-Zr, Ir-Nb-Zr, Ir-Nb-Pt, Ir-Nb-Pt-Al, and Ir-W alloys using a fusion method at 1073 K in sodium peroxide. This was successful, and the concentration of each element was analyzed with ICP-AES. The result was in good agreement with the nominal concentration. This shows that the fusion method in sodium peroxide and analysis with ICP-AES are suitable for Ir alloys.

Sodium carbonate fusion/alkaline solution method for the determination of Si in SiC by inductively coupled plasma-optical emission spectrometry

Dissolution methods with acid solutions have generally been employed for the determination of Si in various samples by inductively coupled plasma-optical emission spectrometry (ICP-OES). However, few reports on analytical procedures with alkaline solutions have been published. Si determination in a SiC sample could be successfully performed by using a dissolution technique with an alkaline solution. The SiC sample (40 mg) in a Pt crucible was fused with 2 g of Na₂CO₃. After the melt was dissolved with water in a Teflon beaker, the solution was finished with a polypropylene flask. The alkaline solution contained Ga added as an internal standard. The solution was diluted to 100 ml and then measured by ICP-OES. For obtaining a calibration curve, SiO₂ powder was dissolved using the same procedure as that for the SiC sample. For a comparison, an acid solution was prepared by adding HCl-HNO₃ to the solution after water-dissolving a SiC sample melted with Na₂CO₃. The acid sample solution contained Zn as an internal standard. A good agreement in the analytical result of Si was obtained between the alkaline sample solution and the acid sample solution.

Dissolution method with HBr-Br₂ for the analysis of Mn-Rh alloys by inductively coupled plasma-optical emission spectrometry

A new dissolution method of a Mn-Rh alloy including trace amounts of Al and Si has been developed for the precise analysis by inductively coupled plasma-optical emission spectrometry (ICP-OES). For the determination of Mn, Rh, Al and Si in Mn-Rh alloy samples (100 mg), the samples were dissolved with 20 ml of HBr-Br₂, followed by the addition of 20 ml of HClO₄ at room temperature; then, most of HBr was decomposed into Br₂ with drops of H₂O₂. The resulting solution was concentrated to about 10 ml after the addition of 10 ml of HNO₃, and MnO₂ was decomposed with H₂O₂ after adding 10 ml of HCl (1+1) and 10 ml of H₂O to obtain a clear solution. Si was determined by a gravimetric method. Moreover, after being measured by ICP-OES, the analytical results were estimated with the sequential correction method.

Purity evaluation of volatile organic compounds by GC-FID for standard gases and solutions using environmental analysis

As the establishment of environmental quality standards is being promoted, the reliability of environmental analysis is one of the most important issues. The environmental problems caused by toxic organic substances in particular have become serious in recent years; therefore, there is much demand for standard gases and solutions for these analyses. Because the exact concentrations of these calibration standards are of great significance to obtain reliable measurement values, the concentrations and uncertainties of these calibration standards are required. Volatile organic compounds (VOCs), such as trichloroethylene and benzene, are part of the emission and environmental quality standards; therefore, the calibration standards of these VOCs are demanded for environmental analysis. To ensure the reliability of these calibration standards, purity evaluations of these VOCs are essential. In many cases the purity of VOC is evaluated by the relative peak area percentage of the main component only by GC-FID analysis for convenience and versatility. However, because of the various kinds of organic compounds, including stabilizers, in the VOC, the sensitivities of the compounds against the main component will be different by GC-FID. Although the identification and measurement of these impurities will offer valuable information for calibration standards and for preparing multi-component standard gases and solutions, these impurities are rarely analyzed. For these reasons, purity evaluations and information on impurities in VOCs have great meaning for preparing standard gases and solutions. The purpose of this study is to establish a purity evaluation method for VOCs by GC-FID to prepare accurate standard gases and solutions. We selected seventeen frequently used VOCs, and attempted to determine each impurity and to estimate their uncertainties. In our work, the internal standard is added directly to the target VOC for a quantitative analysis, rather than using another solvent for dilution. The relative sensitivities of the impurities against the internal standard are measured in advance. As a result, we can analyze trace impurities in VOC precisely, and calculate the purity and uncertainty by the subtraction method. The VOC calibration standards for environmental analysis can be easily provided by the method proposed in this study.