An Experimental Study of Single Component Adsorption/Desorption Isotherms

Wolf, Jeremy; Maaref, Sepideh; Tutolo, Benjamin M.; Kantzas, Apostolos

doi:10.2118/208920-ms

Cited by 3 publications

(1 citation statement)

References 24 publications

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“…The effectiveness of CO 2 sequestration and CH 4 recovery depends on the mole fraction ratio of injected gases. The second option involves highly adsorbing gas into the coal seams, especially CO 2 , which replaces CH 4 in the coal surface due to its higher affinity to the coal surface than CH 4 . − CO 2 adsorption on the coal surface is faster than CH 4 adsorption, and CH 4 replacement by CO 2 is more rapid than the reverse process . CO 2 and CH 4 interact with molecules on the coal surface, changing adsorption energy, molecular bonds, and equilibrium distance.…”

Section: Theorymentioning

confidence: 99%

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications

Mwakipunda,

Wang,

Mgimba

et al. 2023

Energy Fuels

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CO 2 -enhanced coalbed methane (CO 2 -ECBM) technology helps to store CO 2 while producing a clean source of energy (CH 4 ) through the sorption process. This technique can sequester much CO 2 at low temperatures and pressures while recovering CH 4 , which will help offset the associated costs, such as capturing injection gases, drilling and completion infrastructure, compression, and injection expenses. This review paper critically analyzes the CO 2 sequestration potentiality in deep unmineable coal seams. The results revealed that, despite several researchers' insights from proposed concepts, experimental data, modeling and simulations, and pilot tests, there are no reported full field CO 2 -ECBM technology applications for CO 2 sequestration and CH 4 recovery because implementing the projects is uneconomical. Also, CO 2 sequestration and CH 4 recovery effectiveness on coal seams depend on wettability changes of the CO 2 −H 2 O−coal system. The identified research gaps and challenges in this paper are going to help various researchers and shareholders in conducting extra investigations toward full field application of CO 2 sequestration while simultaneously producing a clean source of energy (CH 4 ) in deep unmineable coal seams to meet the Paris climate summit agreement to achieve net zero emissions by 2050 and a maximum global temperature rise of 1.5 °C.

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Section: Theorymentioning

confidence: 99%

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications

Mwakipunda,

Wang,

Mgimba

et al. 2023

Energy Fuels

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An Experimental Study on the Effects of Competitive Adsorption During Huff-N-Puff Enhanced Gas Recovery

Wolf

Maaref

Esmaeili

et al. 2023

Day 1 Wed, March 15, 2023

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Gas is stored in tight reservoirs both as a free gas occupying the pores, and as an adsorbed gas on the rock matrix. Adsorbed gas exhibits liquid-like densities resulting in significantly more gas being stored on the rock surface. This research aims to highlight the effects of competitive adsorption during Huff-n-Puff enhanced gas recovery (EGR) on activated carbon to achieve maximum gas recovery. Pure methane was initially adsorbed by the activated carbon sample in four simple pure component adsorption stages. The methane was then produced in a primary production stage, allowing some methane to desorb from the activated carbon. The free and adsorbed methane was then displaced in five subsequent cyclical injection/production stages with a displacing gas, either nitrogen or carbon dioxide. The experiments were conducted at 30 °C, 45 °C, and 80 °C, and the temperature was maintained using a water bath. The purpose of testing a variety of temperatures was to highlight the effect of temperature on competitive adsorption and recovery factors. From the experiments, adsorption capacity was plotted as a function of the isothermal pressure and methane composition. This data was then fitted with the Extended Langmuir model because of its popularity and simplistic approach for multicomponent gas mixtures. It was observed that total adsorption capacity decreased as a function of temperature for both the nitrogen and carbon dioxide displacement experiments. Selectivity ratios were also determined for each experiment. At all temperatures, carbon dioxide had a higher selectivity ratio over methane compared to the selectivity ratio between nitrogen and methane. Selectivity ratios did not correlate with changing temperatures in both sets of experiments. Recovery factors were also determined for each experiment. Incremental recovery factors progressively decreased with each subsequent production stage. Cumulatively, the carbon dioxide experiments exhibited higher recovery at each temperature tested. For these experiments, irreversibilities were not considered due to the authors’ previous experience with single-component adsorption and desorption experiments on activated carbon [1]. To date, there have not been any EGR Huff-n-Puff experiments conducted on highly porous activated carbon samples with a primary focus on the effect of competitive adsorption. This research aims to highlight the effects of temperature and displacement gas type on the competitive adsorption between methane and nitrogen/carbon dioxide and its impact on the recovery factors. By doing so, EGR schemes can be better understood and modeled with improved inputs for competitive adsorption in each injection and production cycle. This will allow for more accurate production forecasting and help minimize the financial risk of costly EGR projects.

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An Investigation of Multicomponent Gas Flow in Porous Media

Azni

Tutolo

Kantzas

2023

Day 1 Wed, March 15, 2023

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The complex gas dynamics in tight and shale reservoirs have become an important research topic in the oil and gas industry. This study proposes a steady-state flow test using adsorbing and non-adsorbing gases of single and binary gas components through tight adsorbing and non-adsorbing cores to investigate the true permeability value of its diffusion and slip counterparts. A steady-state flow permeability test was chosen to capture the complex gas dynamics in nanopore throats and the presence of organic matter. 1-D experiments in adsorbing (shale) and non-adsorbing (sandstone) cores are conducted under high overburden pressure at room temperature. The pressure difference and gas flow rates across the cores are measured. Helium (base case) is flowed, followed by adsorbing gases (N2 and CH4). This is followed by flowing gas mixtures to verify whether the single component values can be used in multicomponent systems. The results are compared to existing theoretical and analytical models. The apparent gas permeability for shale and sandstone decreases as the gas changes from non-adsorbing to adsorbing. This observation is not in line with the proposed hypothesis of the current models, where the flow mechanisms in tight and shale formations are treated like parallel resistors, where the total permeability is the addition of each component. The adsorbing gas significantly influences gas permeability when comparing the Klinkenberg plots for single and binary gas. The binary gas permeabilities skewed heavily to the gas with higher adsorbing capacity. Besides that, the adsorbing gas permanently changes the shale pore throat morphology by decreasing the pore radius, which significantly affects the flow mechanisms in shale. The study centered on the dissection of the flow mechanisms (viscous flow, surface diffusion, and Knudsen diffusion) contributing to the permeability calculations. Viscous flow dominates the more permeable porous media, while Knudsen diffusion is in the shale. Besides that, the binary gas mixture in a standard steady-state flow test in permeability estimation is introduced. The binary gas mixture in permeability measurement introduces the effect of gas flooding on the measured permeability. The more adsorbing gas actively displaces the less adsorbing gas and contributes to the surface diffusion permeability.

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An Experimental Study of Single Component Adsorption/Desorption Isotherms

Cited by 3 publications

References 24 publications

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications

An Experimental Study on the Effects of Competitive Adsorption During Huff-N-Puff Enhanced Gas Recovery

An Investigation of Multicomponent Gas Flow in Porous Media

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An Experimental Study of Single Component Adsorption/Desorption Isotherms

Cited by 3 publications

References 24 publications

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO2-ECBM Technology: Experimental Studies, Simulation, and Field Applications

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO2-ECBM Technology: Experimental Studies, Simulation, and Field Applications

An Experimental Study on the Effects of Competitive Adsorption During Huff-N-Puff Enhanced Gas Recovery

An Investigation of Multicomponent Gas Flow in Porous Media

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Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications

Recent Advances in Carbon Dioxide Sequestration in Deep Unmineable Coal Seams Using CO₂-ECBM Technology: Experimental Studies, Simulation, and Field Applications