Fractal analysis of the pore structure for clay bound water and potential gas storage in shales based on NMR and N2 gas adsorption

Porosity and pore size distribution (PSD) are essential petrophysical parameters controlling permeability and storage capacity in shale gas reservoirs. Various techniques to assess pore structure have been introduced; nevertheless, discrepancies and inconsistencies exist between each of them. This study compares the porosity and PSD in two different shale formations, i.e., the clay-rich Permian Carynginia Formation in the Perth Basin, Western Australia, and the clay-poor Monterey Formation in San Joaquin Basin, USA. Porosity and PSD have been interpreted based on nuclear magnetic resonance (NMR), low-pressure N2 gas adsorption (LP-N2-GA), mercury intrusion capillary pressure (MICP) and helium expansion porosimetry. The results highlight NMR with the advantage of detecting the full-scaled size of pores that are not accessible by MICP, and the ineffective/closed pores occupied by clay bound water (CBW) that are not approachable by other penetration techniques (e.g., helium expansion, low-pressure gas adsorption and MICP). The NMR porosity is largely discrepant with the helium porosity and the MICP porosity in clay-rich Carynginia shales, but a high consistency is displayed in clay-poor Monterey shales, implying the impact of clay contents on the distinction of shale pore structure interpretations between different measurements. Further, the CBW, which is calculated by subtracting the measured effective porosity from total porosity, presents a good linear correlation with the clay content (R2 = 0.76), implying that our correlated equation is adaptable to estimate the CBW in shale formations with the dominant clay type of illite.

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Composition of the Shales in Niutitang Formation at Huijunba Syncline and its Influence on Microscopic Pore Structure and Gas Adsorption

Petrophysics – The SPWLA Journal of Formation Evaluation and Reservoir Description ◽

10.30632/pjv60n3-2019a1 ◽

2019 ◽

Vol 60 (3) ◽

pp. 373-383

Author(s):

Fu De-liang ◽

◽

Xu Guosheng ◽

Tian Tao ◽

Qin Jian-qiang ◽

...

Keyword(s):

Pore Structure ◽

Gas Adsorption ◽

Niutitang Formation

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PORE STRUCTURE OF TRANSITIONAL SHALES IN THE ORDOS BASIN, NW CHINA: EFFECTS OF COMPOSITION ON GAS STORAGE MECHANISM

10.1130/abs/2017ne-291062 ◽

2017 ◽

Author(s):

Fengyang Xiong ◽

◽

Zhenxue Jiang ◽

Mohammad Amin Amooie ◽

Mohamad Reza Soltanian ◽

...

Keyword(s):

Pore Structure ◽

Ordos Basin ◽

Gas Storage ◽

Nw China ◽

Storage Mechanism ◽

The Ordos Basin

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Influence of tectonic evolution on pore structure and fractal characteristics of coal by low pressure gas adsorption

Journal of Natural Gas Science and Engineering ◽

10.1016/j.jngse.2020.103788 ◽

2020 ◽

pp. 103788

Author(s):

Xiaolei Wang ◽

Yuanping Cheng ◽

Dongming Zhang ◽

Zhengdong Liu ◽

Zhenyang Wang ◽

...

Keyword(s):

Pore Structure ◽

Tectonic Evolution ◽

Gas Adsorption ◽

Low Pressure ◽

Fractal Characteristics

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Fractal Analysis on Pore Structure and Hydration of Magnesium Oxysulfate Cements by First Principle, Thermodynamic and Microstructure-Based Methods

Fractal and Fractional ◽

10.3390/fractalfract5040164 ◽

2021 ◽

Vol 5 (4) ◽

pp. 164

Author(s):

Jiasheng Huang ◽

Wenwei Li ◽

Desheng Huang ◽

Lei Wang ◽

E Chen ◽

...

Keyword(s):

Pore Structure ◽

Fractal Analysis ◽

Equilibrium Phase ◽

Molar Ratio ◽

Hydration Status ◽

First Principle ◽

First Principle Calculation ◽

Cement System ◽

Magnesium Oxysulfate ◽

Modeling Strategy

Magnesium oxysulfate (MOS) cement is a typical eco-friendly cementitious material, which presents excellent performances. In this work, a novel multiscale modeling strategy is proposed to simulate the hydration and pore structure of MOS cement system. This work collected and evaluated the Gibbs free energy of formation for main hydrates and equilibrium constant of main reactions in MOS cement system based on a first principle calculation using Material Studio. Followingly, the equilibrium phase compositions of MOS cement system were simulated through PHREEQC to investigate the molar ratio dependence of equilibrium phase compositions. Results showed that large M (MgO/MgSO4) was beneficial for the formation of 5Mg(OH)2·MgSO4·7H2O (Phase 517) and large H (H2O/MgSO4) tended to decompose MOS cement paste and cause leaching. The microstructure-based method visualized the hydration status of MOS cement systems at initial and ultimate stages via MATLAB and the results showed that large M was significant to reduce porosity, and similar results for the case of small H. Fractal analysis confirms that fractal dimension of pore structure (Df) was significantly decreased after the hydration of MOS and was positively correlated to the porosity of the paste. In addition, it can be referred that large M and small H were beneficial for modifying the microstructure of MOS paste by decreasing the value of Df.

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Formation and development of pore structure in marine-continental transitional shale from northern China across a maturation gradient: insights from gas adsorption and mercury intrusion

International Journal of Coal Geology ◽

10.1016/j.coal.2018.10.005 ◽

2018 ◽

Vol 200 ◽

pp. 87-102 ◽

Cited By ~ 15

Author(s):

Zhaodong Xi ◽

Shuheng Tang ◽

Jing Wang ◽

Guoqiao Yang ◽

Lei Li

Keyword(s):

Pore Structure ◽

Gas Adsorption ◽

Northern China ◽

Mercury Intrusion

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Changes in Pore Structure of Coal Caused by CS2 Treatment and Its Methane Adsorption Response

Geofluids ◽

10.1155/2018/7578967 ◽

2018 ◽

Vol 2018 ◽

pp. 1-11 ◽

Cited By ~ 4

Author(s):

Run Chen ◽

Yong Qin ◽

Pengfei Zhang ◽

Youyang Wang

Keyword(s):

Pore Structure ◽

Adsorption Capacity ◽

Gas Adsorption ◽

Recovery Process ◽

Micropore Volume ◽

Methane Adsorption ◽

Coal Bed ◽

Methane Recovery ◽

Before And After ◽

Key Issues

The pore structure and gas adsorption are two key issues that affect the coal bed methane recovery process significantly. To change pore structure and gas adsorption, 5 coals with different ranks were treated by CS2 for 3 h using a Soxhlet extractor under ultrasonic oscillation conditions; the evolutions of pore structure and methane adsorption were examined using a high-pressure mercury intrusion porosimeter (MIP) with an AutoPore IV 9310 series mercury instrument. The results show that the cumulative pore volume and specific surface area (SSA) were increased after CS2 treatment, and the incremental micropore volume and SSA were increased and decreased before and after Ro,max=1.3%, respectively; the incremental big pore (greater than 10 nm in diameter) volumes were increased and SSA was decreased for all coals, and pore connectivity was improved. Methane adsorption capacity on coal before and after Ro,max=1.3% also was increased and decreased, respectively. There is a positive correlation between the changes in the micropore SSA and the Langmuir volume. It confirms that the changes in pore structure and methane adsorption capacity due to CS2 treatment are controlled by the rank, and the change in methane adsorption is impacted by the change of micropore SSA and suggests that the changes in pore structure are better for gas migration; the alteration in methane adsorption capacity is worse and better for methane recovery before and after Ro,max=1.3%. A conceptual mechanism of pore structure is proposed to explain methane adsorption capacity on CS2 treated coal around the Ro,max=1.3%.

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Influence of Lightweight Aggregate on Durability of High Performance Concrete

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.405-406.197 ◽

2009 ◽

Vol 405-406 ◽

pp. 197-203

Author(s):

Bao Sheng Zhang ◽

Li Juan Kong ◽

Yong Ge

Keyword(s):

Pore Structure ◽

Cement Paste ◽

Frost Resistance ◽

High Performance ◽

High Performance Concrete ◽

Bound Water ◽

Lightweight Aggregate ◽

Normal Weight ◽

Lightweight Aggregate Concrete ◽

Aggregate Concrete

High performance concrete (HPC) with a water/cement ratio (w/c) of 0.32 and different lightweight aggregate (LWA) contents (0%, 25%, 50%, 75%, 100%) were prepared, and the influence of LWA on concrete frost-resistance and impermeability at different ages were studied, as well as the hydration degree, hydrated product, pattern and pore structure of the paste around aggregate. The results show that, by replacing normal weight aggregate (NWA) with 50% and 100% volume contents of pre-wetted LWA respectively, the chemical bound water of the cement paste surrounding aggregate are increased 12.1% and 22.7% as compared to concrete mixed without LWA. And at 28 days, lightweight aggregate concrete has the highest Ca(OH)2 content, whereas the 90-day Ca(OH)2 content of normal weight concrete is the highest. This proves that, with the increase of LWA content in concrete, both of the internal curing effect of pre-wetted LWA and secondary hydration effect of fly ash (FA) are strengthened, this can also be verified by the SEM study. Furthermore, the pore structure of the cement paste around aggregate can be improved consequently. The performance of frost-resistance of HPC can be improved by mixing LWA, the 90 day-frost-resistance of lightweight aggregate concrete is about 2.5 times of that of concrete mixed without LWA. The influence of LWA on the impermeability of HPC is different from normal concrete. When LWA content is more than 50%, the HPC impermeability decreased obviously, however at later age the difference between them becomes minor.

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Experimental Analysis of Pore Structure and Fractal Characteristics of Soft and Hard Coals With Same Coalification

10.21203/rs.3.rs-824436/v1 ◽

2021 ◽

Author(s):

Barkat Ullah ◽

Yuanping Cheng ◽

Liang Wang ◽

Weihua Yang ◽

Izhar Mithal Jiskani ◽

...

Keyword(s):

Pore Structure ◽

Adsorption Capacity ◽

Gas Adsorption ◽

Hysteresis Loops ◽

Control Measures ◽

Practical Significance ◽

Coal Bed ◽

Hard Coal ◽

Pore Surface ◽

Soft Coal

Abstract Accurate and quantitative investigation of the physical structure and fractal geometry of coal has important theoretical and practical significance for coal bed methane and the prevention of dynamic disasters such as coal and gas outbursts. This study investigates the pore structure and fractural characteristics of soft and hard coals using nitrogen and carbon dioxide (N2/CO2) adsorption. Coal samples from Pingdingshan Mine in Henan province of China were collected and pulverized to the required size (0.2-0.25mm). N2/CO2 adsorption tests were performed to evaluate the pore size distribution (PSD), specific surface area (SSA), and pore volume (PV). The pore structure was characterized based on fractural theory. The results unveiled that the strength of coal has a significant influence on pore structure and fracture dimensions. The obvious N2-adsorption isotherms of the coals were verified as Type IV (A) and Type II. The shape of the hysteresis loops indicates the presence of slit-shaped pores. There are significant differences in SSA and PV between both coals. The soft coal showed larger SSA and PV than hard coal that shows consistency with adsorption capacity. The fractal dimensions of soft coal are respectively larger than that of hard coal. The greater the value of D1 (complexity of pore surface) of soft coal is, the larger the pore surface roughness and gas adsorption capacity is. The results enable us to conclude that the characterization of pores and fractures of soft and hard coals is different, tending to different adsorption/desorption characteristics and outburst sensitivity. In this regard, results provide a reference for formulating corresponding coal and gas outburst prevention and control measures.

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