Lasers for plasma diagnostics, time resolved measurement and molecular fluorometry in analytical science

Abstract

In chemical measurement and characterization, lasers are playing a unique role in improving sensitivity, enhancing spatial and spectral resolution, and enabling time resolution on the fastest time scales that are chemically significant. Furthermore, lasers have permitted entirely new classes of measurements to be undertaken that would not be possible without the high radiant power, directionality, and coherence of a laser beam. In this paper, a number of these capabilities are illustrated with examples from the authors' laboratory. Prominent among these examples is the use of a high-power pulsed laser for producing scattering and fluorescence from species in an inductively coupled plasma (ICP). With the appropriate laser and photometric equipment, such measurements enable the determination of time-resolved and spatially resolved values for electron concentration, electron energy distribution, gas-kinetic temperature, and the concentrations of important sample and intrinsic species that the plasma contains. Another example shows how either a continuous wave (CW) or repetitively pulsed laser can be coupled with relatively simple electronic instrumentation to permit measurements to be obtained on a sub-nanosecond time scale. Interestingly, a recent development might obviate the need for a sophisticated laser in such schemes. Lastly, a relatively simple experimental configuration can be used to determine as few as 10⁶ molecules in a real sample. In this arrangement, a single aliquot of the sample is dispensed in a volume as small as 6 nL. This aliquot, in droplet from, then constitutes the sample cell itself. As the droplet falls through the focused laser beam, its contents can be determined with extraordinarily high sensitivity. Methods to improve even this detection capability will be outlined.