Ion chromatographic determination of ammonia in air using a sampling tube of porous carbon.

The ion chromatographic determination of ammonia in air using a sampling tube of porous carbon carbonized at 500 degrees C was examined. When the mean recovery and the reproducibility for a series of five determinations were examined for 1 and 10 ppm ammonia gases, the mean recovery (n = 5) and the relative standard deviation were 97.0% and 3.5% for 1 ppm and 86.9% and 2.8% for 10 ppm, respectively. Furthermore, the recovery from 10 ppm ammonia gas increased with an increase in the extraction time, and a recovery of 99.7% was obtained for 180 min of extraction time. The mean collection efficiency for 1 and 10 ppm ammonia gas was 102.5% and 96.5%, respectively. The relation between the sampling volume and the peak area was linear, and the linearity was 0.999 of the correlation coefficient. The ammonia gas concentration in an actual goat shed could be determined by this sampling device for a sampling volume of 5 L at a flow rate of 1 L/min; 0.79 ppm of the determination value practically agreed as compare with 0.78 ppm from collection by a boric acid solution.     

Bestimmung von stickstoff in refraktärmetallen—II Titan

This is a report on round-robin tests concerning the determination of nitrogen in titanium, which were carried out by the refractory-metals group of the chemical board of the Gesellschaft Deutscher Metallhütten- und Bergleute. The following methods were used: classical and modified Kjeldahl methods, inert gas fusion and vacuum fusion extraction. With the platinum (or palladium) flux technique (noble metal to sample ratio ～ 20 : 1, temperature ? 2000°) the reductive fusion methods are capable of determining nitrogen contents ? 20 ppm. Under special conditions, contents higher than 10–40 ppm can be determined by the Kjeldahl method (the lower limit varies from laboratory to laboratory). With a micro circulating distillation and determination apparatus, and dissolution of the sample within the pressure vessel, the detection limit can be lowered to 1 ppm. Because of possible interferences by reducible nitrogen compounds from the laboratory air, blanks must be determined with high-purity aluminium. The results from 7 laboratories (Kjeldahl 4; reductive fusion 3) for a titanium sample containing 138 ppm nitrogen were in good agreement (standard deviation 5 ppm).     

Trace Spectrophotometric Determination of Dichlorvos using Diphenyl Semicarbazide (DPC) in Environmental and Agricultural Samples

A new and highly sensitive spectrophotometric method is developed for the determination of sub ppm levels of the widely used organophosphorus insecticide dichlorvos. The method is based on alkaline hydrolysis of dichlorvos to dichloroacetaldehyde followed by coupling with diphenyl semicarbazide (DPC) in alkaline medium. The absorption maxima of the wine red dye compound formed is measured at 490 nm. Beer's law is obeyed over the concentration range of 4.3 to 34 μg in a final solution volume of 25 mL (0.18–1.36 ppm). The molar absorptivity, Sandell's sensitivity and correlation coefficient were found to be 2.9 × 10⁵ l mole^?1 cm^?1, 0.013 μg cm^?2 and 0.9999, respectively. The standard deviation and relative standard deviation were found to be ± 0.007 and 1.90%, respectively. The lower limit of detection is 0.04 μg. The method is simple, sensitive and free from interferences of other pesticides and diverse ions. Other organophosphorous pesticides do not interfere with the proposed method. The method has been satisfactorily applied to the determination of dichlorvos in environmental and agricultural samples.     

Extrem nachweisstarkes gas-chromatographisches Bestimmungsverfahren für Selen nach Abtrennung durch Verdampfen im Sauerstoffstrom

For the determination of the smallest amounts of selenium in high-purity copper, the sample (≤2 g) is heated in a quartz tube at 1100–1150°C. SeO₂ evaporates and is collected quantitatively by condensation of the carrier gas in a micro-trap cooled with liquid nitrogen. After evaporation of the oxygen, SeO₂ is caused to react in the trap with 4-nitro-o-phenylenediamine, forming 5-nitropiazselenol, which is then extracted with toluene and determined in the ppb-range by gas-chromatography with ECD. All separation steps were optimized by the tracer method using ⁷⁵Se. Determining 0.74 ppm of Se, the standard deviation was found to be 0.004 ppm for 15 determinations with samples of 200–600 mg. The detection limit is 1 ppb of Se.     

Ion Chromatography for Rapid and Sensitive Determination of Total Chlorine in Water

In this article, we report a new method that involves adsorption, oxygen bomb combustion, and ion chromatography for the preconcentration and determination of adsorbable organic halogen. This method can be divided into four steps, including: macroporous resin adsorption enrichment, optimization, oxygen bomb combustion, and ion chromatography determination. The project studies the macroporous resin adsorb organic halide pollutants and subsequent burn by an oxygen bomb combustion analyzer. The organic halogen in the aerobic environment combusts into hydrogen chloride. The water absorbing hydrogen chloride was then determined by ion chromatography. The influences of some adsorption and combustion parameters, such as the adsorption time, adsorption solution volume, solution pH, hexachlorobenzene acid concentration, combustion oxygen pressure, among others, on their respective adsorption efficiency were investigated. In the optimal condition, the adsorption time was 3.5 h; solution volume was 20 mL; pH was 4; combustion absorption time was 15 min; and the chloride calibration working range was from 1 ppm to 20 ppm (R ²  = 0.9998). Finally, the proposed method was successfully applied to the determination of organic halogen in water samples. The recoveries of chlorine (at spiked concentrations of 10 ppm and 20 ppm into water) in real samples ranged from 92.2% to 101.0%. Intra-day precision (N = 3) in terms of peak area, expressed as relative standard deviation, was found to be within the range of 0.68%–1.97%.     

A new hydrogen cyanide chemiresistor gas sensor based on graphene quantum dots

Graphene quantum dots (GQDs), synthesised via controlled carbonisation of citric acid, were reduced by hydrazine hydrate and then used as hydrogen cyanide (HCN) gas sensors. Checking of the reduction step by Fourier transform infrared spectroscopy (FT-IR) and X-ray photoelectron spectroscopy (XPS) techniques revealed that most of the oxygen-containing functional groups were removed from the GQDs. It was observed the reduction process is necessary for sensitising of GQDs for HCN gas. The electrical resistance of the reduced GQDs was increased as a result of their exposure to HCN gas. Accepting a p-type semiconducting characteristic for GQD material, the above-mentioned behaviour suggested electron donation from HCN to GQD. The sensor response to HCN gas was reversible, suggesting a reversible adsorption/desorption phenomenon of HCN to the GQDs. The response as well as the recovery time of the sensor was different depending on the HCN concentration tested. The developed sensor showed linear HCN response from 1 to 100 ppm. The detection limit of the sensor was estimated to be 0.6 ppm (S/N). Relative standard deviation f HCN determination by the developed sensor was calculated to be 5.7% (n = 4, [HCN] = 50 ppm). The sensor response was did not vary significantly within 6 months.     

Gas chromatographic analysis of trace impurities in chlorine trifluoride

The gas chromatographic determination of trace gaseous impurities in highly reactive fluorinated gaseous matrices presents unique requirements to both equipment and techniques. Especially problematic are the gases normally present in ambient air namely oxygen and nitrogen. Analysing these gases at the low microl/l (ppm) level requires special equipment and this publication describes a custom-designed system utilising backflush column switching to protect the columns and detectors. A thermal conductivity detector with nickel filaments was used to determine ppm levels of impurities in ClF3.     

用天然气气相色谱分析仪快速分析天然气组分及性能参数

介绍用天然气气相色谱分析仪分析天然气中无机组分、有机组分和热值的方法,确定了分析方法和条件,该方法测量结果的相对标准偏差小于1%。采用该方法对制备的标准气体进行了考察,并将该方法用于天然气气体标准物质的性能评价和国际实验室间的比对,天然气组分含量比对相对误差在±1%之内,热量值比对相对误差在±3%之内,取得了国际等效性。     

Substoichiometric isotope dilution analysis of iron in biological materials by the 8-quinolinol-extraction

A highly precise and accurate method for the determination of minor amounts of iron by substoichiometric isotope dilution analysis is described. The constant amount of Fe(III) is substoichiometrically extracted with 2·10⁻⁴M oxine in chloroform from the aqueous phase of pH 9.2–10.0 containing 6·10⁻³M tartrate. The interfering ions such as Mn(II), Co(II), Ni(II), Cu(II), and Zn(II), can be removed by the preliminary extraction of Fe(III) from 7.5M hydrochloric acid solutions into isopropyl ether. The present method has been applied to the determination of iron in biological standard reference materials, i.e., the NBS Spinach (SRM-1570) and the NIES Pepperbush (SRM No. 1), and the results obtained are 548±9 ppm (NBS certified value: 550±20 ppm) and 193±4 ppm, respectively.     

Determination of nitrogen in UN,PuN and (U,Pu)N by oxidation in circulating oxygen and gas chromatographic measurement of the combustion gases

A simple and accurate method for the determination of nitrogen in uranium- and plutonium-bearing materials was developed. The loss of nitrogen by oxidation of the sample before analysis was prevented by pulverizing, weighing and packing the sample into a tin capsule in a glove-box with a high-purity argon atmosphere. Nitrogen was determined by oxidizing the nitrides in the tin capsule in circulating oxygen at 850 °C and analysing the combustion gases by gas chromatography with thermal conductivity detection. The relative standard deviation was about 0.7% and the time required to analyse one sample was about 10 min for successive analyses. Skilled techniques for glove-box work are not necessary. The method is applicable not only to the analysis of research samples but also to the quality control of nitride fuel production lines.     

Liquid Chromatographic Determination of Dimetridazole and Ronidazole in Feeds

Abstract

A simple high performance liquid chromatographic (HPLC) procedure for the simultaneous determination of dimetridazole and ronidazole in turkey feeds is described. The drugs are extracted from feeds by carbon-tetrachloride/dimethylformamide (80:20) at 60°C during 30 mn and the extract is subjected to a partition by water. After centrifugation the eluate is chromatographed on a reverse phase column with ultaviolet detection at 316 nm. Recoveries from samples fortified at levels 2.02 to 7.07 ppm for ronidazole and 2.01 to 7.03 for dimetridazole were 99,6% ± 1,4 and 95,3% ± 1,8 (mean ± standard deviation), respectively.     

Spectrofluorimetric determination of melamine formaldehyde in solid and liquid forms and in wastewater

A new, simple and sensitive spectrofluorimetric method for determination of trace amount of melamine formaldehyde (MF) was developed. In phosphate buffer solution of pH 7.4 MF can remarkably quench the luminescence intensity of toluylene red (NR) at λ_em = 590 nm due to formation of NR-MF ion associate complex. The luminescence intensity of NR-MF complex was in proportion to the concentration of MF and used as photo probe for its determination. The dynamic range for the determination of MF is 7.5–52.5 ppm with detection limit of 4.4 ppm. The method is relatively free from interferences from coexisting substances and used successfully for the determining of MF in powder and liquid forms and in wastewater produced from MF industries. The average recoveries and standard deviations of 98.3 ± 0.6, 98.1 ± 0.6 and 97.3 ± 0.5% were achieved for determination of MF in solid, liquid forms and wastewater, respectively     

1,2,4,6-Tetraphenylpyridinium perchlorate as a reagent for ion-association complex formation and its use for the spectrophotometric determination of gold

The synthesis, characteristics, and applications of 1,2,4,6-tetraphenylpyridinium perchlorate (TPPP) as an agent that forms ion-association complexes is described. This new spectrophotometric analytical reagent forms with AuCl₄^?1 a 1:1 complex which is slightly soluble in water and can be extracted with isopentyl acetate, with maximum absorbance 313 nm, molar absorptivity 3.44 × 10⁴ liters mol^?1 cm^?1. The variables involved in the formation and extraction of the complex in the mentioned organic solvent are studied. In the selected conditions, 1 M hydrochloric acid medium, the extraction efficiency was 95.3%. The apparent stability constant of the complex is log K = 5.9 ± 0.1 at 20 °C. The extracted complex is useful for the spectrophotometric determination of gold in the range of 0.05 to 0.5 ppm. Standard deviation at 0.2 ppm (10 determinations) was 0.0022 and the relative error was ±0.78%.The interferences of many foreign ions are studied, concluding that the procedure proposed shows a high selectivity.The method has been applied satisfactorily to the determination of gold in ores, leads and other materials.     

The solubility and isotopic fractionation of gases in dilute aqueous solution. I. Oxygen

A very precise and accurate new method is described for determination of the Henry coefficient k and the isotopic fractionation of gases dissolved in liquids. It yields fully corrected values for k at essentially infinite dilution. For oxygen the random error for k is less than 0.02%, which is an order of magnitude better than the best previous measurements on that or any other gas. Extensive tests and comparison with other work indicate that systematic errors probably are negligible and that the accuracy is determined by the precision of the measurements. In the virial correction factor (1+λP_t), where P_t is the total pressure of the vapor phase, the coefficient λ for oxygen empirically is a linear decreasing function of the temperature over the range 0–60°C. The simple three-term power series in 1/T proposed by Benson and Krause, $$\ln k = a_0 + a_1 /T + a_2 /T^2 $$ provides a much better form for the variation of k with temperature than any previous expression. With a₀=3.71814, a₁=5596.17, and a₂=?1049668, the precision of fit to it of 37 data points for oxygen from 0–60°C is 0.018% (one standard deviation). The three-term series in 1/T also yields the best fit for the most accurate data on equilibrium constants for other types of systems, which suggests that the function may have broader applications. The oxygen results support the idea that when the function is rewritten as $$\ln k = - (A_1 + A_2 ) + A_1 \left( {\frac{{T_1 }}{T}} \right) + A_2 \left( {\frac{{T_1 }}{T}} \right)^2 $$ it becomes a universal solubility equation in the sense that A₂ is common to all gases, with T₁ and A₁ characteristic of the specific gas. Accurate values are presented for the partial molal thermodynamic function changes for the solution of oxygen in water between the usual standard states for the liquid and vapor phases. These include the change in heat capacity, which varies inversely with the square of the absolute temperature and for which the random error is 0.15%. Analysis of the high-temperature data of Stephan et al., in combination with our values from 0–60°C, shows that for oxygen the fourterm series in 1/T, $$\ln k = - 4.1741 + 1.3104 \times 10^4 /T - 3.4170 \times 10^6 /T^2 + 2.4749 \times 10^8 /T^3 $$ where p=kx and p is the partial pressure in atmospheres of the gas, probably provides the best and easiest way presently available to calculate values for k in the range 100–288°C, but more precise measurements at elevated temperatures are needed. The new method permits direct mass spectrometric comparison of the isotopic ratio³⁴O₂/³²O₂ in the dissolved gas to that in the gas above the solution. The fractionation factor α=³²k/³⁴k varies from approximately 1.00085 (±0.00002) at 0°C to 1.00055 (±0.00002) at 60°C. Although the results provide the first quantitative determination of α vs. temperature for oxygen, it is not possible from these data to choose among several functions for the variation ofInα with temperature. If the isotopic fractionation is assumed to be due to a difference in the zero-point energy of the two species of oxygen molecules, the size of the solvent cage is calculated to be approximately 2.5 Å. The isotopic measurements indicate that substitution of a³⁴O₂ molecule for a³²O₂ molecule in solution involves a change in enthalpy with a relatively small change in entropy.     

Determination of oxygen in ternary uranium oxides by a gravimetric alkaline earth addition method

The applicability of a gravimetric method based on alkaline earth metal addition for the determination of oxygen in ternary uranium oxides of the type M—U—O (M=La, Ce and Th) is described. The oxide sample is mixed with MgO or Ba_2.8UO_5.8 and heated in air under suitable conditions. Because uranium is completely oxidized to the hexavalent state during the reaction, oxygen can be determined from the weight change. Oxygen in La_yU_1-y O_2+x is determined up to y = 0.8 with a standard deviation for x of ±0.006 with MgO. For Th_yU_1-y O_2+x, the value of x is determined with Ba_2.8UO_5.8 with a standard deviation of ±0.01 at y = 0.8. For Ce_yU_1-y O_2+x, the method can be applied only for low cerium concentrations where y = 0–0.2; the value for x with Ba_2.8UO_5.8 at y = 0.2 showed a standard deviation of ±0.002.     

A comparative study of different extraction systems for the spectrophotometric determination of potassium with 18-crown-6

A comparative study on the extractive-spectrophotometric determination of potassium with 18-crown-6 employing different colored counterions and organic extraction solvents is described.Extraction systems using methyl orange/chloroform, bromcresol purple/chloroform and bromcresol green/benzene demonstrated good preliminar features for such purpose and are studied in detail. Analytical performance characteristics including: sensitivity, selectivity, precision, linearity, etc. are given for each method. The main disadvantage of this type of determinations is the lack of reproducibility. Some explanations to this fact are discussed.A new method for the determination of trace amounts of potassium based on its extraction into chloroform with 18-crown-6 and methyl orange is proposed. The linear working range goes from 0.5 to 7 ppm of potassium, the apparent molar absorptivity being 8.8 × 10³ liters mol^?1 · cm^?1, and the precision, expressed in terms of relative standard deviation, of ±4.6%.     

Spectrophotometric determination of periodate and glycerol with 5,5-dimethyl-1,3-cyclohexanedione bisthiosemicarbazone monohydrochloride

A direct spectrophotometric method for the determination of periodate (1—10 ppm) is based on the formation of a yellow oxidation product of 5,5-dimethyl-1,3-cyclohexanedione bisthiosemicarbazone monohydrochloride in aqueous solution at pH 0.5—1.2. The molar absorptivity at 415 nm is 1.72 × 10⁴ l mol^-1 cm^-1. The relative standard deviation is 0.8% for 8.0 ppm periodate. A modification to this procedure is used for the indirect spectrophotometric determination of glycerol (2–10 ppm), via the Malaprade reaction.     

Hydrothermal synthesis of one-dimensional α-MoO3 nanomaterials and its unique sensing mechanism for ethanol

In gas sensor applications, the availability of highly sensitive and rapid response/recovery detector for ethanol gas is sparse. One-dimensional orthogonal crystalline molybdenum trioxide nanomaterials were synthesized by an economical and environmentally friendly hydrothermal method. X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), and energy spectroscopy (EDS) were used to investigate the structure and morphology of the nanometer materials. The relevant characterization shows that nanobelts are highly crystalline layered structures with a width of about 200 nm and a length of a few micrometers. The synthesized ethanol gas sensors based on α-MoO₃ semiconductor material show the highest response at 350 °C. Gas sensitivity tests indicated that α-MoO₃ nanobelts respond well to 50 ～ 600 ppm ethanol at optimal operating temperatures. The selectivity test among various reducing gases shows that the sensor responds better to ethanol compared to other gases such as xylene, NO₂, CO, and H₂ gases. This excellent sensing performance is attributed to the unique sensing mechanism formed in the layered MoO₃ nanobelts through the catalytic reaction between ethanol and MoO₃ lattice oxygen and adsorbed oxygen. The sensing mechanism of the co-catalytic effect of lattice oxygen and adsorbed oxygen on ethanol is also discussed in depth.     

The application of cathodic sputtering to the production of atomic vapours in atomic fluorescence spectroscopy

Cathodic sputtering is used as a source of atomic vapour for the chemical analysis of metals and alloys by atomic fluorescence spectroscopy. The sputtered vapour is produced in a Pyrex glow-discharge chamber which is suitable for the rapid interchange of flat, metallic samples. The discharge operates with a water-cooled cathode specimen and a flow-through gas control system. Linear calibration curves are obtained for the determination of nickel, chromium, copper, manganese and silicon in some iron-base alloy standards. For nickel, chromium and copper, detection limits are of the order of 20 ppm in the iron, and for manganese and silicon about 70 and 400 ppm respectively. The reproducibility of the fluorescence measurements is about ±1%. The system can be readily adapted to provide simultaneous multi-element analysis.