Your search keyword '"Hongjian Zhu"' showing total 3 results

1. Nanoscale mineralogy and organic structure characterization of shales: Insights via AFM-IR spectroscopy.

Author

Hongjian Zhu, Yanjun Lu, Yanyan Pan, Peng Qiao, Ali Raza, and Wei Liu

Subjects

*MINERALOGY, *OIL shales, *SPECTROMETRY, *MICROSTRUCTURE, *ORGANIC chemistry

Abstract

Atomic force microscopy coupled with infrared spectroscopy (AFM-IR) is one of the most effective and widely employed mixed techniques capable of providing direct access to infrared spectroscopic imaging and chemical analysis at the nanoscale spatial resolution. In this communication, AFM-IR was applied to the evaluate the in-situ nanoscale mineralogy and to characterize the organic structure of shale. Significant chemical and microstructural heterogeneity could be observed on the mirror-like surface of naturally deformed shale. It was also apparent that slickensides formed on the mirror-like surface potentially influence the spatial distribution of organic matter. This technique provides an effective combination for direct and in-situ studies of the morphology and physicochemical properties of geological rocks at the nanoscale, opening a new avenue for investigations to help reveal some complex geological phenomena, such as organic carbon graphitization and mineral transformation during fault deformation. Furthermore, this technique makes it possible to determine the chemical composition, molecular structure and functional group information of shale organic matter, which is crucial information for investigating the hydrocarbon generation potential, maturity evaluation, and oil and gas migration mechanisms in shale. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanical characterization of uniaxial compression associated with lamination angles in shale.

Author

Ming Gao, Manping Yang, Yanjun Lu, Levin, V. A., Pei He, and Hongjian Zhu

Subjects

MECHANICAL behavior of materials, SHALE gas, COMPUTED tomography, ROCKS, DATA analysis

Abstract

This paper investigates the mechanical properties and damage laws of marine shale from the Silurian Longmaxi Formation by conducting uniaxial compression experiments with varying lamination angles with respect to the loading direction. Data are analyzed via computed tomography scanning and fractal theory to reveal a series of mechanical properties, considering stress-strain curve, compressive strength, Young's modulus, and Poisson's ratio. The results indicate three damage modes in shale samples: shear, tensionshear, and tension. The shales are anisotropic as the mechanical properties vary with the lamination orientation and the loading direction. The compressive strength decreases nonlinearly with increasing lamination angle, whereas the Young's modulus and Poisson's ratio correlate almost linearly with the lamination angle. To overcome the defect of visual images when quantitatively evaluating cracks and rock damage to investigate the mechanical properties of shale, we propose block fractal dimension and crack fractal dimensions calculated using post-experimental photographs and computed tomography images. Fractal dimensions are useful tools for identifying variations in uniaxial compressive strength and correlate positively with the sample damage, particularly their damage class. This study highlights the value of applying fractal theory for the quantitative characterization of shale mechanical properties, and reveals that the lamination orientation to the loading direction is a parameter that significantly controls the mechanical properties of shale. [ABSTRACT FROM AUTHOR]

Published

2024

3. Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity.

Author

Jian Gao, Xiaoshi Li, Guoxi Cheng, Hua Luo, and Hongjian Zhu

Subjects

SHALE gas, PETROLEUM prospecting, GAS storage, ORGANIC compounds, PLATE tectonics, GAS reservoirs

Abstract

Shale gas exploration and development have taken significant strides in the relatively straightforward intra-basin stability zone and intra-basin weak deformation zone of marine shale in the Sichuan Basin, South China. In addition, the extra-basin strong tectonic modification zones have been actively explored. However, the results have been limited, which reveals the complexity of shale gas formation and preservation conditions in the context of multi-scale geological processes. These tectonic geological conditions have a significant impact on the shale gas content, while it has been difficult to figure out how tectonic deformation modifies reservoir structure and what specific mechanism causes shale gas content anomalies. Based on subjecting geologic samples to combined high-temperature and high-pressure experiments, this study summarizes the tectonic constraint mechanism of shale petrophysical structure evolution and its impact on shale gas storage, reveals the intrinsic connection and mechanism of shale pore-fracture and organic matter, inorganic mineral particle structure evolution and tectonic stress, and identifies the remodeling mechanism of the shale reservoir physical property change. The findings contribute to the theory of shale deformation and gas accumulation, as well as offer a scientific foundation for the exploration of marine shale gas in the complex tectonic zones outside the Sichuan Basin. [ABSTRACT FROM AUTHOR]

Published

2023