Crossed-beam thermal lens spectrometry is especially designed for the detection of very small samples in capillary tubes and more generally in microfluidic devices. In this work, the effect of the size of the excitation beam with respect to the size of the sample microchannel has been investigated. Although the signal is inversely proportional to the size of the excitation waist into the sample, the use of large waists may provide greater sensitivities when short-pulse excitation lasers are used and allows easier optimization of the optical design. On the contrary, the use of small beam waists reduces the edge effects that can arise depending on the nature and thickness of the walls of the sample holder. Moreover, small beams provide better spatial resolution and have allowed the measurement of flow velocities as low as 1 mm s(-1).
This work investigates the efficiency of a chaotic micromixer using thermal lens spectrometry. The outlet of the mixing device was connected to a thermal lens detection head integrating the probe beam optical fibers and the sample capillary. The chaotic micromixer consisted of a Y-shaped poly(dimethylsiloxane) (PDMS) microchip in which ribbed herringbone microstructures were etched on the floor of the main channel. Due to the solvent composition dependence of the thermal lens response, the photothermal method was shown to be highly sensitive to nonhomogeneous mixing compared to fluorescence detection. The apparatus was applied to the determination of Fe2+ with 1,10-phenanthroline using flow injection analysis; a limit of detection of 11 microg L(-1) of iron was obtained.
The aim of this work was to perform highly localized spectroscopic surface measurements by combining time-resolved laser spectroscopy and scanning near-field optical microscopy. The final purpose of that was to study surface sorption at the molecular level of trivalent ions in the framework of nuclear waste disposal assessment. Time-resolved laser spectroscopy presents the advantages of being selective, sensitive, and noninvasive and scanning near-field optical microscopy is a promising technique for high resolution surface speciation. Investigation of the interaction between trivalent europium and a monocrystalline alumina (1102) surface was made using different conditions of concentration and pH. We found that the distribution of sorbed europium was always homogeneous with a decay time of europium (III) equal to 350 micros+/-15 micros. On the other hand, carbonate species with a decay time of 210 micros+/-10 micros or other hydroxide species with a decay time of 180 micros+/-10 micros were detected on the surface when a higher concentration or a higher pH solution, respectively, were used. Distribution of these species was heterogeneous and their associated fluorescence signal was relatively high, evoking a precipitated form. X-ray photoelectron spectroscopy (XPS) was also used on the same samples as a complementary technique. A binding energy of 1135.1 eV was obtained for the sorbed europium and another binding energy of 1134.4 eV was obtained for the hydroxide species, thus confirming the presence of two kinds of species on the surface.
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