Applying plasma acoustic and image information for underwater LIBS normalization

Improving the stability of underwater LIBS is a key point for its practical use in oceanic applications. The traditional normalization method of using the internal standard element is often limited in some practical cases due to the lack of a suitable element as a reference. In this study, we compared three external normalization strategies by using plasma acoustic signals, plasma images, and the acoustic-image combination. The acoustic signals were measured with two types of hydrophone (needle hydrophone and spherical hydrophone), and the plasma images were recorded with a low-cost CCD camera. The characteristics of the acoustic signals were studied first, and the correlations of the acoustic intensities and image intensities with the LIBS spectral intensities were analyzed. Then, three normalization models were established respectively based on the acoustic data, image data, and acoustic-image combined data using the partial least squares regression (PLSR). It shows that acoustic normalization has a comparable performance on the reduction of spectral fluctuation versus image normalization, while the acoustic-image combined normalization works more efficiently than using the acoustic or image normalization only. Calibration curves of Mn, Sr, and Li were also built with the three normalization methods, and the obtained results demonstrated the availability of applying plasma acoustic signals and plasma images in improving the analytical performances of underwater LIBS.

Automated summary

Improving the stability of underwater LIBS is crucial for its practical application in marine settings. This study compares three external normalization strategies using plasma acoustic signals, plasma images, and the combination of acoustic and image data. It is found that acoustic normalization is comparable to image normalization in reducing spectral fluctuation, while the acoustic-image combined normalization method is more efficient. These methods enhance the analytical performance of underwater LIBS.