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Quantification of total carbon in soil using laser-induced breakdown spectroscopy: a method to correct interference lines.

Authors :
Nicolodelli G
Marangoni BS
Cabral JS
Villas-Boas PR
Senesi GS
Dos Santos CH
Romano RA
Segnini A
Lucas Y
Montes CR
Milori DM
Source :
Applied optics [Appl Opt] 2014 Apr 01; Vol. 53 (10), pp. 2170-6.
Publication Year :
2014

Abstract

The C cycle in the Brazilian forests is very important, mainly for issues addressed to climate changes and soil management. Assessing and understanding C dynamics in Amazonian soils can help scientists to improve models and anticipate scenarios. New methods that allow soil C measurements in situ are a crucial approach for this kind of region, due to the costs for collecting and sending soil samples from the rainforest to the laboratory. Laser-induced breakdown spectroscopy (LIBS) is a multielemental atomic emission spectroscopy technique that employs a highly energetic laser pulse for plasma production and requires neither sample preparation nor the use of reagents. As LIBS takes less than 10 s per sample measurement, it is considered a promising technique for in situ soil analyses. One of the limitations of portable LIBS systems, however, is the common overlap of the emission lines that cannot be spectrally resolved. In this study a method was developed capable of separating the Al interference from the C emission line in LIBS measurements. Two typical forest Brazilian soils rich in Al were investigated: a spodosol (Amazon Forest) and an oxisol (Atlantic Forest). Fifty-three samples were collected and analyzed using a low-resolution LIBS apparatus to measure the intensities of C lines. In particular, two C lines were evaluated, at 193.03 and 247.86 nm. The line at 247.86 nm showed very strong interference with Fe and Si lines, which made quantitative analysis difficult. The line at 193.03 nm showed interference with atomic and ionic Al emission lines, but this problem could be solved by applying a correction method that was proposed and tested in this work. The line at 247.86 was used to assess the proposed model. The strong correlation (Pearson's coefficient R=0.91) found between the LIBS values and those obtained by a reference technique (dry combustion by an elemental analyzer) supported the validity of the proposed method.

Details

Language :
English
ISSN :
1539-4522
Volume :
53
Issue :
10
Database :
MEDLINE
Journal :
Applied optics
Publication Type :
Academic Journal
Accession number :
24787177
Full Text :
https://doi.org/10.1364/AO.53.002170