Details

Autor(en) / Beteiligte

• Jiang, Tian-Jia
• Yang, Meng
• Li, Shan-Shan
• Ma, Ming-Jun
• Zhao, Nan-Jing
• Guo, Zheng
• Liu, Jin-Huai
• Huang, Xing-Jiu

Titel

In Situ Underwater Laser-Induced Breakdown Spectroscopy Analysis for Trace Cr(VI) in Aqueous Solution Supported by Electrosorption Enrichment and a Gas-Assisted Localized Liquid Discharge Apparatus

Ist Teil von

• Analytical chemistry (Washington), 2017-05, Vol.89 (10), p.5557-5564

Ort / Verlag

United States: American Chemical Society

Erscheinungsjahr

2017

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Traditional laser-induced breakdown spectroscopy (LIBS) always fails to directly detect target in aqueous solution due to rapid quenching of emitted light and adsorption of pulse energy by surrounding water. A method is proposed for the in situ underwater LIBS analysis of Cr­(VI) in aqueous solution freed from the common problems mentioned above by combining a gas-assisted localized liquid discharge apparatus with electrosorption for the first time. In this approach, the introduction of the gas-assisted localized liquid discharge apparatus provides an instantaneous gaseous environment for underwater LIBS measurement (that is, the transfer of sampling matrix is not needed from aqueous solution to dry state). The preconcentration of Cr­(VI) is achieved by electrosorption with a positive potential applied around adsorbents, which can promote the adsorption of Cr­(VI) and inhibit that of the coexisting cations leading to a good anti-interference. Amino groups functionalized chitosan-modified graphene oxide (CS–GO) is utilized for Cr­(VI) enrichment, which can be protonated to form NH3 + in acidic condition promoting the adsorption toward Cr­(VI) by electrostatic attraction. The highest detection sensitivity of 5.15 counts μg–1 L toward Cr­(VI) is found for the optimized electrosorption potential (E ES = 1.5 V) and electrosorption time (t ES = 600 s) without interference from coexisting metal ions. A corresponding limit of detection (LOD) of 12.3 μg L–1 (3σ method) is achieved, which is amazingly improved by 2 or even 3 orders of magnitude compared to the previous reports of LIBS.