NanoSIMS sulfur isotopic analysis at 100 nm scale by imaging technique

NanoSIMS sulfur isotopic analysis at 100 nm scale by imaging technique

NanoSIMS has been widely used for sulfur isotopic analysis ( S and S) of micron-sized grains or complex zoning in sulfide in terrestrial and extraterrestrial samples. However, the conventional spot mode analysis is restricted by depth effects at the spatial resolution < 0.5-1 μm. Thus sufficient...

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Bibliographic Details
Published in:Frontiers in chemistry Vol. 11; p. 1120092
Main Authors: Hao, Jia-Long, Zhang, Liu-Ping, Yang, Wei, Li, Zhao-Yang, Li, Rui-Ying, Hu, Sen, Lin, Yang-Ting
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 16-03-2023
Subjects:
analytical precision
Chemistry
isotopic images
NanoSIMS
spatial resolution
sulfur isotope analysis
NanoSIMS
spatial resolution
analytical precision
sulfur isotope analysis
isotopic images
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Summary:NanoSIMS has been widely used for sulfur isotopic analysis ( S and S) of micron-sized grains or complex zoning in sulfide in terrestrial and extraterrestrial samples. However, the conventional spot mode analysis is restricted by depth effects at the spatial resolution < 0.5-1 μm. Thus sufficient signal amount cannot be achieved due to limited analytical depths, resulting in low analytical precision (1.5‰). Here we report a new method that simultaneously improves spatial resolution and precision of sulfur isotopic analysis based on the NanoSIMS imaging mode. This method uses a long acquisition time (e.g., 3 h) for each analytical area to obtain sufficient signal amount, rastered with the Cs primary beam of ∼100 nm in diameter. Due to the high acquisition time, primary ion beam (FCP) intensity drifting and quasi-simultaneous arrival (QSA) significantly affects the sulfur isotopic measurement of secondary ion images. Therefore, the interpolation correction was used to eliminate the effect of FCP intensity variation, and the coefficients for the QSA correction were determined with sulfide isotopic standards. Then, the sulfur isotopic composition was acquired by the segmentation and calculation of the calibrated isotopic images. The optimal spatial resolution of ∼ 100 nm (Sampling volume of 5 nm × 1.5 μm ) for sulfur isotopic analysis can be implemented with an analytical precision of ∼1‰ (1SD). Our study demonstrates that imaging analysis is superior to spot-mode analysis in irregular analytical areas where relatively high spatial resolution and precision are required and may be widely applied to other isotopic analyses.
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John Cliff, Pacific Northwest National Laboratory (DOE), United States
Reviewed by: Kexue Li, The University of Manchester, United Kingdom
Edited by: Zihua Zhu, Pacific Northwest National Laboratory (DOE), United States
This article was submitted to Analytical Chemistry, a section of the journal Frontiers in Chemistry
ISSN:2296-2646
2296-2646
DOI:10.3389/fchem.2023.1120092