Impact of Degassing Time and Temperature on the Estimation of Pore Attributes in Shale

Singh, Deependra Pratap; Chandra, Debanjan; Vishal, Vikram; Hazra, Bodhisatwa; Sarkar, Pinaki

doi:10.1021/acs.energyfuels.1c02201

Cited by 22 publications

(17 citation statements)

References 67 publications

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“…Low-temperature subcritical physisorption studies are used routinely to characterize the porous structures of a wide range of materials. In the case of shales and kerogens, it is essential to ensure that representative sampling is undertaken for an appropriate particle size range and that degassing conditions are precisely controlled. − Most of the adsorption research for both sub- and supercritical adsorption has used samples, which have been degassed under a high vacuum at 383 K, so that all adsorbed water vapor and CO 2 were removed. ,,, This temperature was used to ensure the removal of adsorbed water without significant modification of the shale structure and gives a baseline for adsorption measurements for a dry sample.…”

Section: Adsorption Methodsmentioning

confidence: 99%

“…32−35 Most of the adsorption research for both sub-and supercritical adsorption has used samples, which have been degassed under a high vacuum at 383 K, so that all adsorbed water vapor and CO 2 were removed. 12,13,34,36 This temperature was used to ensure the removal of adsorbed water without significant modification of the shale structure and gives a baseline for adsorption measurements for a dry sample.…”

Section: Concept Of Gibbs Surface Excessmentioning

confidence: 99%

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Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Thomas

2023

Energy Fuels

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Shale gas from unconventional resources will contribute to meeting the energy demand during the transition to a net-zero carbon economy. In this minireview, the current status of understanding methane adsorption on kerogens and shales is discussed in relation to methane storage capacity. Standard subcritical adsorption studies provide characterization data (micropore volumes, total pore volumes, surface areas, and pore size distributions) for the porous structures of shales and kerogens. However, supercritical methane adsorption measurements under simulated geological conditions are necessary to assess realistic methane adsorption storage capacities. Supercritical methane adsorption on shale and shale components (kerogens and clays) under high pressure and temperature conditions that simulated geological conditions is compared. Kerogen structural characteristics are discussed in relation to supercritical methane isotherms and isobars. The contribution of adsorbed methane gas relative to “free” or compressed gas to the total gas stored in shale is considered. The importance of kerogens in both storage of the adsorbed phase and as the source of methane is highlighted, and the areas where knowledge and understanding are deficient are identified, in particular, the relationship of kerogen type and maturity with supercritical methane adsorption under simulated geological conditions. The competitive adsorption of water on methane capacity is also an area where more detailed studies are necessary. These are challenges to address gaps in the current knowledge and understanding, which require future research.

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Section: Adsorption Methodsmentioning

confidence: 99%

Section: Concept Of Gibbs Surface Excessmentioning

confidence: 99%

Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Thomas

2023

Energy Fuels

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“…Organic-hosted porosity is one of the most critical elements in successful shale plays. Different techniques viz., imaging (e.g., broad ion beam-scanning electron microscopy, and focused ion beam-scanning electron microscopy), gas adsorption (low pressure and high pressure gas adsorption techniques), mercury intrusion porosimetry, neutron scattering (e.g., ultrasmall/small angle neutron scattering), etc., are used to assess shale porosity. ,,,− In addition to several factors, such as the presence of surface functional groups, the mesopores and micropores, and the specific surface area, etc., thermal maturity levels have been identified to strongly control the development of organic porosity and, hence, the gas adsorption capacity of shales and carbonaceous matter. − Loucks et al observed organic nanopore development to be strongly dependent on the thermal maturity levels of the samples and inferred that this is essentially caused by the conversion of kerogen to hydrocarbons and the formation of pores within the organic matter in the process.…”

Section: Co2 Adsorption Versus Ch4 Desorption: Vis-à-vis Co2 Sequest...mentioning

confidence: 99%

Impact of Supercritical CO₂ on Shale Reservoirs and Its Implication for CO₂ Sequestration

et al. 2022

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Hydraulic fracturing has transformed the international energy landscape by becoming the go-to method for the exploitation of natural gas from unconventional shale reservoirs. However, in the recent years, the search for an alternative method of shale-gas exploration has intensified, because of various problems (e.g., contamination of ground and surface water, overexploitation of precious water resources, air pollution, etc.) associated with the usage of water-based fracturing techniques. The use of CO2 for shale gas exploitation has emerged as a better alternative to aqueous-based gas exploration techniques. CO2 when injected into deep shale reservoirs, transitions into supercritical CO2 (SC-CO2) when temperature and pressure condition exceeds the critical point, i.e., 31.1 °C and 7.38 MPa. In this paper, we comprehensively review the impact of SC-CO2 on shale gas reservoirs during the different stages of shale-gas exploration, i.e., (i) drilling, which involves the superiority of SC-CO2 over water-based drilling fluids, in terms of achieving under-balanced well condition, higher rates of penetration, and resistance to formation damage; (ii) fracturing, which involves factors affecting the tortuosity of fractures created by SC-CO2 fracturing, breakdown pressure, and proppant-carrying capacity; and (iii) injection, which involves the twin-headed benefit of enhanced recovery due to CO2/CH4 competitive adsorption and geological sequestration, CO2 vs CH4 excess sorption as a function of pressure, etc. Several research works have indicated discrepancies on how SC-CO2 impacts different shale properties. Some studies show low-pressure N2-gas-adsorption-derived surface area and total pore volume to be increasing with SC-CO2 imbibition, while others show a decreasing trend for the same. Similarly, for some shales, the quartz content, along with the clay mineral contents, decreased as the exposure to SC-CO2 increased, while in some other studies, with similar long-term exposure to SC-CO2, the quartz content was observed to increase along with the decrease in clay content and vice versa. Essentially, the increased exposure to SC-CO2 results in the dissolution of primary porous structures and fractures, and reformation of newer porous structure and conduits in shales. Nonetheless, these changes in the mineralogy weaken the microstructure of the rock bringing significant changes in the mechanical properties of the shales with implications on the wellbore stability and fracturing efficiency. The mechanical properties such as uniaxial compressive strength (UCS), Young’s modulus, and tensile strength decrease as the SC-CO2 saturation period increases. However, some studies have shown factors like bedding angle and phase-state of CO2 having varying effect on the strength behavior of the shales. Moreover, changes in the structure of shales caused by the creation of fractures and the reduction of their strength can also pose major risks, because of potential leakage of CO2 through these created pathways. How these processes would i...

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“…Different pretreatment methods have a significant influence on the measured results. Different pretreatment methods have a significant influence on the measured results . Low-temperature nitrogen adsorption experimental process was carried out in accordance with GB/T 21650.2-2008 (determination of pore size distribution and porosity of solid materials by the mercury intrusion method and gas adsorption method) in this study.…”

Section: Methodsmentioning

confidence: 99%

“…Different pretreatment methods have a significant influence on the measured results. 53 Low-temperature nitrogen adsorption experimental process was carried out in accordance with GB/T 21650.2-2008 (determination of pore size distribution and porosity of solid materials by the mercury intrusion method and gas adsorption method) in this study. Before the test, the samples were dried (120 °C, 24 h) and then degassed ( Note: I is illite; S is smectite; I/S is illite/smectite interlayer; %S is interlayer ratio; C is chlorite.…”

Section: Samples and Methodsmentioning

confidence: 99%

Water Distribution in Marine Shales: Based on Two-Dimensional Nuclear Magnetic Resonance and Low-Temperature Nitrogen Adsorption

Guo

et al. 2023

Energy Fuels

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A significant amount of foreign fluid is kept in the marine shale reservoirs after hydraulic fracturing. The water distribution characteristics in the pore space are quite complex because of the shale’s significant inhomogeneity. The change in reservoir water status brings new challenges to studying the adsorption and flow capacity of shale gas, which also brings difficulties to assessing the geological reserves of shale reservoirs and capacity prediction and development. In this study, based on a two-dimensional nuclear magnetic resonance technique and low-temperature nitrogen adsorption technique, clay minerals, organic matter, and marine shale were used as the study objects to get the distribution characteristics of water in shale pores. The results show that after entering the shale reservoir, most of the water is adsorbed on the surface of inorganic pores, mostly clay pores, to create a bound water film with a thickness of around 0.96 nm. Shale pores’ diameter, volume, and surface area are all smaller in the wet state compared to the dry, falling by 10.11, 47.02, and 71.00%, respectively. Small-scale pores (D < 10 nm) are better at absorbing water, and the water in these pores fills the spaces between them to create capillary water besides being adsorbed on the pore surface. Bound water can aid in the development of gas reservoirs and the desorption of adsorbed gas, but the capillary water column obstructs the flow of gas and restricts the flow of shale gas in microscopic pores. This study will lay a theoretical foundation for evaluating the water-bearing characteristics of marine shale reservoirs, which will help analyze the modification effect of fracturing fluid retention on reservoir water-bearing characteristics and then guide gas well development.

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Impact of Degassing Time and Temperature on the Estimation of Pore Attributes in Shale

Cited by 22 publications

References 67 publications

Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Impact of Supercritical CO₂ on Shale Reservoirs and Its Implication for CO₂ Sequestration

Water Distribution in Marine Shales: Based on Two-Dimensional Nuclear Magnetic Resonance and Low-Temperature Nitrogen Adsorption

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Impact of Degassing Time and Temperature on the Estimation of Pore Attributes in Shale

Cited by 22 publications

References 67 publications

Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Perspectives of Gas Adsorption and Storage in Kerogens and Shales

Impact of Supercritical CO2 on Shale Reservoirs and Its Implication for CO2 Sequestration

Water Distribution in Marine Shales: Based on Two-Dimensional Nuclear Magnetic Resonance and Low-Temperature Nitrogen Adsorption

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Product

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Impact of Supercritical CO₂ on Shale Reservoirs and Its Implication for CO₂ Sequestration