Comparison of gated and non-gated detectors for double-pulse laser induced plasma analysis of trace elements in iron oxide

Double-pulse laser-induced breakdown spectroscopy (LIBS) is an emerging technique for accurate compositional analysis of many different materials. We present results of collinear double-pulse LIBS for analysis of the trace elements aluminum, phosphorus and boron in sintered iron oxide targets. The samples were ablated in air by double-pulse Nd:YAG laser radiation (6 ns pulse duration, laser wavelength of 532 nm) and spectra were recorded with an Echelle spectrometer equipped either with a CCD (charge coupled device) or an ICCD (intensified charge coupled device) camera. For the trace elements aluminum and phosphorus, the use of the CCD detector system resulted in considerable higher signal-to-noise ratios and/or better limits of detection compared to the results achieved with the ICCD detector. The use of CCD double-pulse LIBS enables to detect low concentrations of phosphorus with a limit of detection of 10 ppm by evaluating the UV line at 214.91 nm, which overlaps with a Fe I line. Compared to the ICCD system, the CCD system requires the accumulation of a higher number of laser double-pulses to achieve acceptable signal quality. This can be disadvantageous for elements showing pronounced depletion effects as for the trace element boron in sintered iron oxide targets.

► Direct comparison of double-pulse LIBS analysis using CCD and ICCD detectors ► Double-pulse LIBS technique for monitoring of trace elements in iron oxide ► CCD detector can result in better signal-to-noise ratios and limits of detection. ► Low P concentrations detectable by CCD double-pulse LIBS of the line at 214.91 nm ► CCD system disadvantageous for elements showing pronounced depletion effects