Mid-infrared sensors for hydrocarbon analysis in extreme environments.
Degree: PhD, Chemistry and Biochemistry, 2010, Georgia Tech
A number of MIR sensing platforms and methods were developed in this research work demonstrating potential applicability of MIR spectroscopy for studying hydrocarbon systems in extreme environments.
First of all, the quantitative determination of the diamondoid compound adamantane in organic media utilizing IR-ATR spectroscopy at waveguide surfaces was established. The developed analytical strategy further enabled the successful detection of adamantane in real world crude oil samples. These reported efforts provide a promising outlook for detection and monitoring of diamondoid constituents in naturally occurring crudes and petroleum samples.
IR-ATR spectroscopy was further utilized for evaluating and characterizing distribution, variations, and origin of carbonate minerals within sediment formations surrounding a hydrocarbon seep site - MC 118 in the Gulf of Mexico. An analytical model for direct detection of 13C-depleted authigenic carbonates associated with cold seep ecosystems was constructed. Potential applicability of IR-ATR spectroscopy as direct on-ship - and in future in situ - analytical tool for characterizing hydrocarbon seep sites was demonstrated.
MIR evanescent field absorption spectroscopy was also utilized to expand the understanding on the role of surfactants during gas hydrate formation at surfaces. This experimental method allowed detailed spectroscopic observations of detergent-related surface processes during SDS mediated gas hydrate formation. The obtained IR data enabled proposing a mechanism by which SDS decreases the induction time for hydrate nucleation, and promotes hydrate formation. Potential of MIR fiberoptic evanescent field spectroscopy for studying surface effects during gas hydrate nucleation and growth was demonstrated.
Next, quantifying trace amounts of water content in hexane using MIR evanescent field absorption spectroscopy is presented. The improvement in sensitivity and of limit of detection was obtained by coating an optical fiber with layer of a hydrophilic polymer. The application of the polymer layer has enabled the on-line MIR detection of water in hexane at low ppm levels. These results indicate that the MIR evanescent filed spectroscopy method shows potential for in-situ detection and monitoring of water in industrial oils and petroleum products.
Finally, quantification of trace amounts of oil content in water using MIR evanescent field absorption spectroscopy is reported. Unmodified and modified with grafted hydrophobic polymer layer silver halide optical fibers were employed for the measurements. The surface modification of the fiber has enabled the on-line MIR analysis of crude oil in water at the low ppb level. Potential application of MIR fiber-optic evanescent field spectroscopy using polymer modified waveguides toward in-situ low level detection of crude oil in open waters was demonstrated.
Advisors/Committee Members: Boris Mizaikoff (Committee Chair), Thomas Orlando (Committee Co-Chair), Facundo Fernandez (Committee Member), Jiri Janata (Committee Member), Oliver Brand (Committee Member), Seong-Soo Kim (Committee Member).
Subjects/Keywords: MIR spectroscopy; IR-ATR spectroscopy; Diamondoids; Gas hydrates; Water-crude oil emulsions; MIR sensing platforms; Hydrocarbons; Infrared detectors; Infrared technology
to Zotero / EndNote / Reference
APA (6th Edition):
Luzinova, Y. (2010). Mid-infrared sensors for hydrocarbon analysis in extreme environments. (Doctoral Dissertation). Georgia Tech. Retrieved from http://hdl.handle.net/1853/41156
Chicago Manual of Style (16th Edition):
Luzinova, Yuliya. “Mid-infrared sensors for hydrocarbon analysis in extreme environments.” 2010. Doctoral Dissertation, Georgia Tech. Accessed January 21, 2021.
MLA Handbook (7th Edition):
Luzinova, Yuliya. “Mid-infrared sensors for hydrocarbon analysis in extreme environments.” 2010. Web. 21 Jan 2021.
Luzinova Y. Mid-infrared sensors for hydrocarbon analysis in extreme environments. [Internet] [Doctoral dissertation]. Georgia Tech; 2010. [cited 2021 Jan 21].
Available from: http://hdl.handle.net/1853/41156.
Council of Science Editors:
Luzinova Y. Mid-infrared sensors for hydrocarbon analysis in extreme environments. [Doctoral Dissertation]. Georgia Tech; 2010. Available from: http://hdl.handle.net/1853/41156