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dc.contributor.authorLiu, K.
dc.contributor.authorOstadhassan, M.
dc.contributor.authorHackley, P.C.
dc.contributor.authorGentzis, T.
dc.contributor.authorZou, Jie
dc.contributor.authorYuan, Yujie
dc.contributor.authorCarvajal-Ortiz, H.
dc.contributor.authorRezaee, Reza
dc.contributor.authorBubach, B.
dc.date.accessioned2022-11-02T05:56:20Z
dc.date.available2022-11-02T05:56:20Z
dc.date.issued2019
dc.identifier.citationLiu, K. and Ostadhassan, M. and Hackley, P.C. and Gentzis, T. and Zou, J. and Yuan, Y. and Carvajal-Ortiz, H. et al. 2019. Experimental Study on the Impact of Thermal Maturity on Shale Microstructures Using Hydrous Pyrolysis. Energy and Fuels. 33 (10): pp. 9702-9719.
dc.identifier.urihttp://hdl.handle.net/20.500.11937/89582
dc.identifier.doi10.1021/acs.energyfuels.9b02389
dc.description.abstract

Hydrous pyrolysis was applied to four low-maturity aliquots from the Utica, Excello, Monterey, and Niobrara Shale Formations in North America to create artificial maturation sequences, which could be used to study the impact of maturation on geochemical and microstructural properties. Modified Rock-Eval pyrolysis, reflectance, organic petrology, and Fourier transform infrared spectroscopy (FTIR) were employed to analyze their geochemical properties, while gas adsorption (CO2 and N2) was used to characterize their pore structures (pores < 200 nm). Organic petrography using white and blue light (fluorescence) before and after hydrous pyrolysis showed that amorphous organic matter cracked into solid bitumen, oil, and gas during hydrous pyrolysis. A reduction of the CH2/CH3 ratio in hydrous pyrolysis residues was observed from FTIR analysis. Rock-Eval pyrolysis showed that kerogens in the four samples were dissimilar, and hydrous pyrolysis residues showed smaller hydrogen index and Sh2 values than starting materials. Results from CO2 and N2 gas adsorption analysis showed that pore structures (micropore volume, micropore surface area, meso-macropore volume, and meso-macropore surface area) changed significantly during hydrous pyrolysis. However, changes in pore structure were dissimilar among the four samples, which was attributed to different activation energies of organic matter. A thermodynamic fractal model showed a decrease in fractal dimensions of Utica, Monterey, and Excello after hydrous pyrolysis, indicating a decrease in surface roughness. The pore size heterogeneity in the Utica sample increased as hydrous pyrolysis temperature increased, whereas the pore size heterogeneity distributions in the Monterey and Excello decreased based on the N2 adsorption data.

dc.languageEnglish
dc.publisherAMER CHEMICAL SOC
dc.subjectScience & Technology
dc.subjectTechnology
dc.subjectEnergy & Fuels
dc.subjectEngineering, Chemical
dc.subjectEngineering
dc.subjectSURFACE FRACTAL DIMENSION
dc.subjectNANOMETER-SCALE PORES
dc.subjectOIL-SHALE
dc.subjectORGANIC-MATTER
dc.subjectSIZE DISTRIBUTION
dc.subjectEVOLUTION
dc.subjectGENERATION
dc.subjectPOROSITY
dc.subjectMORPHOLOGY
dc.subjectFRACTIONS
dc.titleExperimental Study on the Impact of Thermal Maturity on Shale Microstructures Using Hydrous Pyrolysis
dc.typeJournal Article
dcterms.source.volume33
dcterms.source.number10
dcterms.source.startPage9702
dcterms.source.endPage9719
dcterms.source.issn0887-0624
dcterms.source.titleEnergy and Fuels
dc.date.updated2022-11-02T05:56:20Z
curtin.departmentWASM: Minerals, Energy and Chemical Engineering
curtin.accessStatusFulltext not available
curtin.facultyFaculty of Science and Engineering
curtin.contributor.orcidRezaee, Reza [0000-0001-9342-8214]
curtin.contributor.researcheridRezaee, Reza [A-5965-2008]
dcterms.source.eissn1520-5029
curtin.contributor.scopusauthoridRezaee, Reza [39062014600]


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