A Portable Spark-Induced Breakdown Spectroscopic (SIBS) Instrument and its Analytical Performance

Iyll-Joon Doh; Carmen Gondhalekar; Carmen Gondhalekar; Valery Patsekin; Bartek Rajwa; Bartek Rajwa; Keegan Hernandez; Euiwon Bae; J. Paul Robinson; J. Paul Robinson

doi:10.1364/AS.73.000698

Applied Spectroscopy
Vol. 73,
Issue 6,
pp. 698-708
(2019)
•https://doi.org/10.1364/AS.73.000698

A Portable Spark-Induced Breakdown Spectroscopic (SIBS) Instrument and its Analytical Performance

Iyll-Joon Doh, Carmen Gondhalekar, Valery Patsekin, Bartek Rajwa, Keegan Hernandez, Euiwon Bae, and J. Paul Robinson

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Iyll-Joon Doh, Carmen Gondhalekar, Valery Patsekin, Bartek Rajwa, Keegan Hernandez, Euiwon Bae, and J. Paul Robinson, "A Portable Spark-Induced Breakdown Spectroscopic (SIBS) Instrument and its Analytical Performance," Appl. Spectrosc. 73, 698-708 (2019)

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Abstract

A compact spark-induced plasma spectroscopic device was developed to detect elements used in a variety of applications. The system consists of a spark generator connected to tungsten electrodes, a custom-built delay generator, and two spectrometers that together cover the ultraviolet visible (UV–Vis) range (214–631 nm). The system was evaluated by qualitatively and quantitatively sampling copper standards. Prominent spectral peaks were identified using the NIST database for atomic emissions. The effectiveness of the proposed system was also tested with a lanthanide sample (gadolinium) and provided qualitative identification of the characteristic peaks. A semi-quantitative measurement for silicon and gold was performed using variable amounts of each particulate. Silica microbeads in solution were applied to paper wafers, while gold nanoparticles were sputter-coated onto silicon wafers. Results showed a positive correlation between the intensity of the signal and the concentration of each type of particulate. The variation of signal intensity was investigated to determine the repeatability, and the coefficient of variation was lowered from 60% to 25% after averaging measurements of multiple ablations per observation.

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Applied Spectroscopy