Characterization of Kerogen and Source Rock Maturation Using Solid-State NMR Spectroscopy

Clough, A. R.; Sigle, Jessica L.; Jacobi, David; Sheremata, Jeff M.; White, Jeffery L.

doi:10.1021/acs.energyfuels.5b01669

Cited by 30 publications

(36 citation statements)

References 24 publications

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“…The use of solid‐state NMR was investigated by Clough et al as a non‐destructive technique to directly assess the organic matter inside the source rock. [ 133 ] The authors successfully determined the composition of several kerogen, bitumen and source rock samples with 1 H, 13 C direct excitation, and 13 C cross polarization solid‐state NMR under MAS. With 129 Xe NMR using the Fraissard approach, [ 24 ] the authors were able to correlate the decreasing size of mesopores with increasing thermal maturity of the samples, thus introducing 129 Xe NMR as a straightforward, non‐destructive tool.…”

Section: Recent Applicationsmentioning

confidence: 99%

¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications

Wisser

Hartmann

2020

Adv Materials Inter

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A large number of functional and catalytic materials exhibit porosity, often on different length scales and with a hierarchical structure. The assessment of pore sizes, pore geometry, and pore interconnectivity is complex and usually not feasible by classical spectroscopic and diffraction techniques. One of the most powerful methods to probe these parameters is nuclear magnetic resonance (NMR) spectroscopy of xenon, which is introduced into the pore system. Adsorbed to the pore walls, it acts as probe nucleus. In this tutorial review, an introduction into the basic principles of 129Xe NMR spectroscopy and the models developed to determine pore sizes in different materials are given. The possibilities and limitations of this method for obtaining insights into hierarchical structures of functional materials are highlighted and a review of recent works is presented.

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Section: Recent Applicationsmentioning

confidence: 99%

¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications

Wisser

Hartmann

2020

Adv Materials Inter

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“…Direct characterization of carbon molecular species (molecular structures) in kerogen and other carbonaceous materials complements the analysis of bulk elemental abundances and is performed using solid-state spectroscopic techniques. These techniques include 13 C nuclear magnetic resonance (NMR), ,− infrared (IR), − ,,,,− Raman, ,, and X-ray photoelectron spectroscopy (XPS) . These approaches enable analysis of bulk, solid, unaltered OM, preserving molecular structural information that is otherwise lost using thermal decomposition techniques.…”

Section: Universal Curves Describing Evolution Of Type II Kerogen Pro...mentioning

confidence: 99%

Universal Curves Describing the Chemical and Physical Evolution of Type II Kerogen during Thermal Maturation

et al. 2020

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This paper synthesizes and interprets literature data relating to the chemical and physical characteristics of kerogen (solid, insoluble sedimentary organic matter) representing more than a dozen petroliferous sedimentary basins across four continents, 400 million years of sedimentation, and burial histories ranging from thermally immature to overmature. The studied kerogen properties include chemical composition (elemental composition and carbon and heteroatom speciation), physical properties (skeletal density), nuclear responses (petrophysical properties), and microstructure (surface area). As occurs in the vast majority of economically significant conventional and unconventional petroliferous sedimentary basins, the kerogens are observed to be predominantly or entirely paleo-marine (derived from marine plankton and algae) and classified as so-called type II kerogen. The analysis described here reveals that that the wide range of chemical and physical properties of type II kerogen is explained nearly entirely by its extent of thermal maturation and is independent of basin location, age, and other basin-specific characteristics, such as formation lithology. The analysis results in a series of universal curves relating many type II kerogen properties to thermal maturity, with correlation coefficients typically of 0.85−0.90. The indistinguishable property−maturity relationships among type II kerogen in petroleum-bearing formations globally make it possible to infer its relevant chemical and physical characteristics only from knowledge of the thermal maturity of the organic matter. As shown by example, this presents substantial practical benefit for unconventional shale exploration and appraisal because chemical, physical, and petrophysical properties of kerogen are critical in such workflows but are nearly always unknown and otherwise impractical to measure in typical industrial projects.

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“…In the kerogen structure, aromatics that are linked by aliphatic and heteroatoms [15], in which solid bitumen can be trapped [61,62]. The increase in carbon aromaticity that takes place during maturation has been also detected during natural maturation that is caused by igneous intrusions [63][64][65][66][67][68], or by the increase in depth of burial [69][70][71].…”

Section: Pi = S1mentioning

confidence: 99%

Evaluating Molecular Evolution of Kerogen by Raman Spectroscopy: Correlation with Optical Microscopy and Rock-Eval Pyrolysis

Khatibi

Ostadhassan

Tuschel³

et al. 2018

Energies

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Vitrinite maturity and programmed pyrolysis are conventional methods to evaluate organic matter (OM) regarding its thermal maturity. Moreover, vitrinite reflectance analysis can be difficult if prepared samples have no primary vitrinite or dispersed widely. Raman spectroscopy is a nondestructive method that has been used in the last decade for maturity evaluation of organic matter by detecting structural transformations, however, it might suffer from fluorescence background in low mature samples. In this study, four samples of different maturities from both shale formations of Bakken (the upper and lower members) Formation were collected and analyzed with Rock-Eval (RE) and Raman spectroscopy. In the next step, portions of the same samples were then used for the isolation of kerogen and analyzed by Raman spectroscopy. Results showed that Raman spectroscopy, by detecting structural information of OM, could reflect thermal maturity parameters that were derived from programmed pyrolysis. Moreover, isolating kerogen will reduce the background noise (fluorescence) in the samples dramatically and yield a better spectrum. The study showed that thermal properties of OM could be precisely reflected in Raman signals.

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Characterization of Kerogen and Source Rock Maturation Using Solid-State NMR Spectroscopy

Cited by 30 publications

References 24 publications

¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications

¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications

Universal Curves Describing the Chemical and Physical Evolution of Type II Kerogen during Thermal Maturation

Evaluating Molecular Evolution of Kerogen by Raman Spectroscopy: Correlation with Optical Microscopy and Rock-Eval Pyrolysis

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Characterization of Kerogen and Source Rock Maturation Using Solid-State NMR Spectroscopy

Cited by 30 publications

References 24 publications

129Xe NMR on Porous Materials: Basic Principles and Recent Applications

129Xe NMR on Porous Materials: Basic Principles and Recent Applications

Universal Curves Describing the Chemical and Physical Evolution of Type II Kerogen during Thermal Maturation

Evaluating Molecular Evolution of Kerogen by Raman Spectroscopy: Correlation with Optical Microscopy and Rock-Eval Pyrolysis

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¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications

¹²⁹Xe NMR on Porous Materials: Basic Principles and Recent Applications