Determination of polar aniline derivatives in aqueous environmental samples using on-line liquid chromatographic preconcentration techniques

Summary On-line precolumn sample handling is used to enrich polar aniline derivatives in order to preconcentrate them prior to their separation. Liquid-solid extraction is possible with a cation-exchanger precolumn after acidification of water samples at pH 3 and a clean-up in order to remove the high amounts of inorganic cations present in natural samples. Since inorganic removal cannot be total, overloading of the ion exchanger occurs rapidly. The volume which can be directly percolated through the cation-exchanger precolumn cannot exceed 30 ml and the amount preconcentrated is not sufficient for a determination at the 100 ppt level. A two-step preconcentration procedure is carried out in order to increase the sample volume: the direct percolation of samples through the cation-exchanger precolumn is avoided and the clean-up step is no longer necessary. Aniline derivatives are preconcentrated in their neutral form at pH 7 by a 9-cm long column packed with the copolymer-based PRP-1 sorbent; then, a small volume of water-methanol at pH 2 allows the cationic compounds alone to be desorbed from the PRP-1 column in their protonated form and to be transferred to a 1-cm long cation-exchanger precolumn. This precolumn is then coupled to an analytical C18 column and its content on-line analysed by an acetonitrile gradient. The PRP-1 column acts as a powerful filter to many neutral interferents and aniline derivatives can be thus determined from 150-ml drinking water samples with 10–50 ppt UV detection limits.Dedicated to Roland W. Frei     

Trace-level determination of polar phenolic compounds in aqueous samples by high-performance liquid chromatography and on-line preconcentration on porous graphitic carbon

The use of porous graphitic carbon (PGC) was investigated for the trace enrichment and the on-line liquid chromatographic separation of polar phenolic compounds (phenol, di- and trihydroxybenzenes, aminophenols, etc.) from aqueous samples. Comparison between retentions obtained with PGC and with the copolymer-based sorbent PRP-1 showed similar variations of the capacity factors with the mobile phase composition, but an inverse retention order. The capacity factor of a very polar analyte, such as 1,3,5-trihydroxybenzene (phloroglucinol), is 1000 in pure water, whereas this analyte is not retained by C₁₈-silica and is poorly retained by PRP-1 (k′ = 3 in water). A precolumn packed with PGC can be coupled to a PGC analytical column for simple separation in the reversed-phase mode. This methodology has been applied to the direct determination of pyrocatechol, resorcinol and phloroglucinol below the 0.1 μg/1 level in a 50-ml sample.     

Fourier Transform Spectroscopy of the O(2) Herzberg Bands

From absorption spectra obtained at high resolution by coupling a Fourier transform spectrometer to a long-path multiple reflection cell [A. Jenouvrier, M.-F. Mérienne, B. Coquart, M. Carleer, S. Fally, A. C. Vandaele, C. Hermans, and R. Colin, J. Mol. Spectrosc. 198, 136-162 (1999)] the intensities of the O(2) Herzberg bands (A(3)Sigma(+)(u)-X(3)Sigma(-)(g), c(1)Sigma(-)(u)-X(3)Sigma(-)(g), A'( 3)Delta(u)-X(3)Sigma(-)(g)) have been studied at ambient temperature. The integrated cross section values are given for the lines of the (v'-0) bands in the A(3)Sigma(+)(u)-X(3)Sigma(-)(g), c(1)Sigma(-)(u)-X(3)Sigma(-)(g), and A'( 3)Delta(u)-X(3)Sigma(-)(g) transitions with v' = 0-11, v' = 2-19, and v' = 2-12, respectively. The band oscillator strengths have been deduced and transition moments have been calculated. The total absorption values in the region of the Herzberg bands together with the photoabsorption values determined previously above the dissociation limit can be modeled by a single curve, in agreement with the continuity relationship of the cross sections through the dissociation limit. Copyright 2000 Academic Press.     

The 1Σ+-X1Σ+ transition of the PN molecule

The recently observed ¹Σ⁺-X¹Σ⁺ transition of the PN molecule (J. Phys. B.13, 2251–2254 (1980)) has been photographed at high dispersion in the 1600–1900-Å region. A rotational analysis is carried out and shows 11 vibrational levels of the new ¹Σ⁺ state. These levels are perturbed and absolute vibrational numbering cannot be determined. Some perturbations can be accounted for by interactions with the A¹Π state. Weakening of lines are explained as accidental predissociations and allow us to discuss the dissociation energies of the X¹Σ⁺ and A¹Π states.     

New valence and Rydberg states of the P18O molecule

The absorption spectrum of the P¹⁸O molecule has been studied in the region 1650–1800 Å. The upper levels of the transitions are shown to be levels of new ²Π valence, ²Π Rydberg and ²Δ Rydberg states of the PO molecule. Most of the levels are perturbed; some of them are predissociated. The new valence state P²Π corresponds to a regular state of the electronic configuration $\text{σ}{}^2\text{π}{}^3\text{π}{}^{12}$ and the ²Π and ²Δ Rydberg states belong to the 5p, 3d, 4d complex series. Perturbations of the P²Π state are shown to arise from Rydberg ～ Non Rydberg interactions with states of same or different symmetry. The complexity of the interactions does not allow to carry out a deperturbation but a comparison with the data of the P¹⁶O molecule allows to give a vibrational assignment to the levels of the P²Π state.     

Fourier Transform Spectroscopy of the O(2) Herzberg Bands. III. Absorption Cross Sections of the Collision-Induced Bands and of the Herzberg Continuum

Absorption spectra of molecular oxygen were measured in the laboratory under temperature and pressure conditions prevailing in the Earth's atmosphere. Spectra of pure O(2), O(2) + N(2), and O(2) + Ar were recorded in the 41 700 to 33 000 cm(-1) region (240-300 nm) at a maximal optical path difference of 0.45 cm using a Fourier transform spectrometer and a multiple reflection gas cell. The different components of the spectra, namely the discrete bands of the three Herzberg systems, the Herzberg continuum, and the collision-induced diffuse Wulf bands, were separated. The contribution of the Herzberg bands was first subtracted using the line parameters determined previously [A. Jenouvrier, M.-F. Mérienne, B. Coquart, M. Carleer, S. Fally, A. C. Vandaele, C. Hermans, and R. Colin, J. Mol. Spectrosc. 198, 136-162 (1999)] from high-resolution data. Spectra recorded at various pressures then made it possible to determine by linear regression the intensity of the Wulf bands and the Herzberg continuum. The characteristics of the Wulf bands have been investigated in details: vibrational analysis, pressure effect, foreign gas effect, and a simulated spectrum are reported. The Herzberg continuum cross section is determined below the dissociation limit. A comparison with literature data is given. The new O(2) absorption cross sections and O(2)-O(2) collision-induced absorption cross sections are useful in connection with atmospheric measurements of ozone and other trace gases in the UV spectral region. Copyright 2000 Academic Press.     

Trace-level monitoring of chloroanilines in environmental waters using on-line trace-enrichment and liquid chromatography with UV and electrochemical detection

Summary An on-line procedure is described for the trace-level determination of mono-, di- and methyl-chloroanilines in aqueous samples using selective preconcentration with a cation-exchanger and liquid chromatography with UV and electrochemical detection. Because direct percolation through a cation-exchanger has to be avoided owing to the high content of inorganic anions present in natural waters, a two-step on-line preconcentration was carried out: chloroanilines were first trapped on a precolumn packed with an apolar polymeric sorbent (PRP-1) in their neutral form. Then the PRP-1 precolumn was coupled in series with a second precolumn containing cation exchange material. The chloroanilines were removed from the first precolumn with 3 mL of deionised water: acetonitrile (31) at pH 1 and retained by the cation exchange column. The contents of the cation exchange column were finally desorbed onto the analytical column and eluted with a water: acetonitrile gradient. The combination of selective trace enrichment and sensitive electrochemical detection allows the simultaneous determination of chloroanilines from 150 mL of river water samples with detection limits below 30 ng/l. Identification is confirmed by the selective preconcentration and the two detection modes.