Study on Gas Adsorption–Desorption and Diffusion Behaviour in Coal Pores Modified by Nano Fracturing Fluid

Zuo, Wei; Qi, Mingrui; Liu, Yanwei; Li, Huai-Zhen; Han, Hongkai; Wang, Yan; Long, LV; Wu, Shengjie

doi:10.1021/acsomega.3c02227

Cited by 2 publications

(1 citation statement)

References 15 publications

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“…In order to investigate the methane absorption, desorption, and diffusion capacities in various coal samples, Zuo et al employed both experimental and molecular simulation techniques. They then suggested an enhanced fracturing fluid formulation consisting of 0.8% CATB + 0.2% NaSal + 1% KCl + SiO 2 [9].…”

Section: Methane Adsorption Materialsmentioning

confidence: 99%

Materials Enabling Methane and Toluene Gas Treatment

Lv,

Wang

2024

Materials

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This paper summarizes the latest research results on materials for the treatment of methane, an important greenhouse gas, and toluene, a volatile organic compound gas, as well as the utilization of these resources over the past two years. These materials include adsorption materials, catalytic oxidation materials, hydrogen-reforming catalytic materials and non-oxidative coupling catalytic materials for methane, and adsorption materials, catalytic oxidation materials, chemical cycle reforming catalytic materials, and degradation catalytic materials for toluene. This paper provides a comprehensive review of these research results from a general point of view and provides an outlook on the treatment of these two gases and materials for resource utilization.

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Section: Methane Adsorption Materialsmentioning

confidence: 99%

Materials Enabling Methane and Toluene Gas Treatment

Lv,

Wang

2024

Materials

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Methane Desorption–Diffusion Behaviors in Micropores of Coal under Different Water Displacement Pressures

Ni,

Zhang,

Han

et al. 2024

Langmuir

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Hydraulic fracturing not only enhances the flow conductivity of coal seams but also transforms the CH 4 adsorbed in coal seams into free CH 4 and then outputs it via the desorption−diffusion process, thus improving the output quantity and efficiency of CH 4 . In this paper, taking the coal from Changping mine in Shanxi as the research object, the 3D macromolecule model of coal was established by using analytical test experiments, and the molecular dynamics simulation method of desorption and diffusion was applied to study the characteristics of methane desorption rate and diffusion behaviors under different driving water pressures through the parameters of gas−water concentration distribution, desorption and diffusion rates, and the interaction energies between the coal and the gas−liquid. The results show that the water drive can increase the desorption rate of methane. With the increase of methane adsorption pressure, the desorption effect of water drive becomes stronger and then weaker. The desorption effect of water drive was best when the methane adsorption pressure was 5 MPa and the pressure difference was 2 MPa. Generally, the water drive promoted the methane diffusion, but if the water drive time was too long, it formed a water plug, and the water drive methane inhibited the diffusion. In shallow reservoirs, water drive can obviously promote the desorption−diffusion of methane. The binding energy between CH 4 molecules is mainly composed of the repulsive force, while that between water molecules is mainly the adsorption force. In the binding energy between CH 4 molecules and coal structures, the van der Waals (VDW) force accounts for 99% of the effect; in the binding energy between water molecules and coal structures, the electrostatic force contributes 84% to ∼88% thereto. The VDW force is significantly influenced by the pressure, while the electrostatic force is slightly affected. As the water displacement differential pressure is increased, the binding energy between CH 4 molecules and coal structures decreases.

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Study on Gas Adsorption–Desorption and Diffusion Behaviour in Coal Pores Modified by Nano Fracturing Fluid

Cited by 2 publications

References 15 publications

Materials Enabling Methane and Toluene Gas Treatment

Materials Enabling Methane and Toluene Gas Treatment

Methane Desorption–Diffusion Behaviors in Micropores of Coal under Different Water Displacement Pressures

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