Determination of nitrophenols,diaminotoluenes, and chloroaromatics in ammunition wastewater

Methods for the determination of three compound classes, i. e. diaminotoluenes, nitrophenols, and chloroaromatics in groundwater of a former ammunition plant are reported. Diaminotoluenes were extracted by discontinuous liquid/liquid-, nitrophenols by continuous liquid/liquid-extraction using dichloromethane, and chloroaromatics by solid-phase extraction. These compound classes may be analyzed by gas chromatography (GC) or gas chromatography coupled to mass spectrometry (GC/MS) without derivatization or after derivatization with N-methyl-bis(trifluoroacetamide) (MBTFA) or heptafluorobutyric anhydride (HFBA) in the case of diaminotoluenes and HFBA or acetic anhydride in the case of nitrophenols. An atomic emission detector (AED) coupled to a gas chromatograph may be employed for the analysis of chloroaromatics. High selectivity can be achieved using the characteristic wavelengths of chlorine. A variety of these compounds were identified and quantified in a groundwater sample from the former ammunition plant Elsnig (Saxony, Germany). Concentrations were in the lower ppb range. Thus, dichlorobenzenes which may have been used as substituents at the end of World War II could be identified in groundwater samples at this site.     

Trace analysis of quaternary aminoalcohols as degradation products from softeners in wastewater

The sensitive and selective determination of polyalcohols without chromophores or fluorophores in the lower ppb-level is still an analytical task of high interest, especially in the field of environmental investigations. This paper describes a cation-exchange HPLC procedure for the separation and fluorescence detection of two quaternary ammonium compounds with polyalcoholic groups (degradation products of fabric softener) after derivatization with 9-fluorenylmethyl chloroformate (FMOC). Detailed experiments were carried out to determine optimum reaction conditions (pH, reaction time, temperature), linear range, detection limits, and kinetics of the reaction. The HPLC separation on a cation-exchange column includes a gradient program which provides complete separation from neutral compounds also reacting with FMOC and its hydrolysis products formed during the reaction in alkaline medium. High specificity for both investigated ammonium compounds with detection limits in the range of 1 ppb could be achieved.     

Nachweis von Industriechemikalien (HPS,BPS und SPS) im Oberflächenwasser

Occurrence of Industrial Chemicals (HPS, BPS, and SPS) in Surface Water The paper gives the results of water examinations for different phenylsulfonamides. Random samples taken every month between May 1999 and August 2000 from surface water out of the river Rhine (kilometer 838), the river Ruhr (Mülheim Styrum) and the river Emscher (Oberhausen center) were tested for the corrosion inhibiting agent 6‐[methyl(phenylsulfonyl)amino]‐hexanoic acid (HPS) as well as its metabolites 4‐[methyl‐(phenylsulfonyl)amino]‐butanoic acid (BPS) and sarkosin‐N‐(phenylsulfonyl) (SPS). Furthermore, the sewage plant effluents of two municipal wastewater treatment plants from the rural area were also included in the monitoring program. The analytical method includes solid‐phase extraction (SPE), a derivatization step as well as gas chromatography mass spectrometry (GC‐MS). SPS is regularly found in all investigated surface waters, but only occasionally in the effluents of the two rural sewage plants. The median values for SPS amount to 0.09 μg/L in the river Rhine, 0.60 μg/L in the river Ruhr, and 0.70 μg/L in the river Emscher. BPS can only be found in the river Ruhr (median value: 0.08 μg/L) and in the river Emscher (median value: 0.41 μg/L). HPS was regularly found in a surface water for the first time. This substance can be detected in the Emscher through the whole measurement period. The median value for HPS amounts to 1.78 μg/L. Aditionally, the validation characteristics of an alternative analytical method including solid‐phase microextraction (SPME) is worked out. The fully automated process includes an on‐fiber methylation step and the GC‐MS. The repeatability standard deviation of the process amounts to RSD < 12%. Detection limits between 0.07 and 0.70 μg/L are achieved.     

Determination of Organic Phosphonates in Aqueous Samples Using Liquid Chromatography/Particle-beam Mass Spectrometry

Organic phosphonates are widely used, and in general, they are not easily biodegradable. Therefore, our interest was focussed on the development of an analytical method for the trace-level determination of organic phosphonates in water. Our method combines preconcentration of the analytes by evaporating the water sample with the methylation of the phosphonates using diazomethane. Analysis of the totally methylated phosphonates is done by liquid chromatography coupled with mass Spectrometry by the particle-beam interface. The derivatives could be clearly identified by their electron impact mass spectra as well as their chemical ionisation mass spectra. The totally methylated phosphonates can be separated by liquid chromatography using a 125 mm × 4 mm LiChrospher 100 Diol column and a gradient mobile phase containing n-hexane and isopropyl alcohol. After optimizing preconcentration and derivatization procedures as well as all particle-beam and mass spectra conditions, detection limits in the low ppb range were attained.     

Speciation of Polysulfides and Zerovalent Sulfur in Sulfide-rich Water Wells in Southern and Central Israel

Zerovalent sulfur and inorganic polysulfides were determined in nine sulfide-rich water wells in central and southern Israel. Although the two locations belong to the same aquifer, they are characterized by different pH and hydrogen sulfide levels. Hydrogen sulfide in the central Israel wells ranged between 19 and 32 μM, and the pH was 7.26 ± 0.07. The southern basin is characterized by lower water circulation, lower pH (around 6.8), and higher hydrogen sulfide levels (>470 μM). Polysulfides were determined by a rapid single-phase methylation using methyl trifluoromethanesulfonate (methyl triflate) reagent. The summary polysulfide concentration for S₄²⁻–S₇²⁻ species was found to be around 0.14–0.75 μM in the central region of Israel and substantially higher, 2.3–4.6 μM in the southern region. The sum of polysulfide zerovalent sulfur and colloidal sulfur was quantitatively detected by cyanide derivatization and compared to polysulfide sulfur determined by methyl triflate derivatization and to the chloroform extraction of zerovalent sulfur. A method for the determination of sulfur undersaturation level—the ratio between dissolved elemental sulfur and its equilibrium concentration in the presence of solid sulfur—based on the observed levels of the major polysulfide species is described. The observed polysulfide speciation was compared with the predicted speciation under sulfur saturation conditions taking into account the water temperature, its ionic strength, and pH. Criteria for sulfur saturation versus unsaturated conditions were established based on (1) the chain length dependence of the ratio between the observed polysulfide concentrations and their predicted value under sulfur saturated conditions, and (2) the difference between the concentration of zerovalent sulfur, as determined by cyanolysis, and the total polysulfide sulfur. According to this dual criterion five of the water wells were classified as being undersaturated with respect to sulfur, though for all the examined water wells the majority of the zerovalent sulfur was in the form of polysulfide sulfur.     

MATHEMATICAL MODEL FOR THE OPTIMIZATION OF THE REACTION BETWEEN 2,3-BIS(m-TOLYL)QUINOLIZINIUM BROMIDE AND PIPERIDINE USING A FACTORIAL DESIGN

A number of nucleophiles have been successfully identified and quantified using the Krhnke reactionwith 2,3,-diphenyl derivatives of quinolizinium salts.Optimization of the reaction conditions by meansof a mathematical model involving analysis of the response surface has led to a better understanding ofthe factors exerting an influence on the above reaction.The parameters chosen were temperature,reaction time,base concentration,water concentration andnucleophile concentration.The reaction was developed in polar aprotic solvents(acetone,acetonitrile).To facilitate the nucleophilic attack,the presence of an organic base(triethylamine)was necessary,although concentrations in excess of 0.15M did not alter the development of the reaction.Sincepharmaceutical solutions are often aqueous,the influence of water on the reaction was studied.Lowwater volumes have no significant influence on the opening of the quinolizinium ring by the nucleophilicreagent.However,when the water proportion exceeded that of the organic solvent,the fluorescenceintensity was lower than expected.Development of the fluorescent reaction product was first detected5 min after the reaction started.The fluorescence intensity reached its optimum value after 138 min.     

A new extraction technique for in situ analyses of amino and carboxylic acids on Mars by gas chromatography mass spectrometry

In order to target key organic compounds in the Martian regolith using gas chromatography mass spectrometry (GC-MS), we have developed a new extraction procedure coupled with chemical derivatization. This new technique was tested on a Mars analog soil sample collected from the Atacama Desert in Chile. We found that amino and carboxylic acids can be extracted from the Atacama soil in a 1:1 mixture of isopropanol and water after ultrasonic treatment for 30 min. The extracted organic compounds were then derivatized in a single-step reaction using N-methyl-N-(tert-butyldimethylsilyl)-trifluoroacetamide (MTBSTFA) as the silylating agent in order to transform these compounds into volatile species that can then be detected by GC-MS. We are currently developing a miniaturized reaction cell suited for spaceflight, where both organic extraction and chemical derivatization processes can take place in a single step.