A Mercury Intrusion Porosimetry Method for Methane Diffusivity and Permeability Evaluation in Coals: A Comparative Analysis

Fang, Xianglong; Cai, Yidong; Liu, Dameng; Zhou, Yingfang

doi:10.3390/app8060860

Cited by 21 publications

(12 citation statements)

References 39 publications

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“…The cementation exponent was also set to the value of 2. This is the lower limit for m found by Fang et al (2018) for coal using gas diffusion measurements. The model showed a reasonable fit to the measured s 0 for the 2% sand-biochar mixtures (Fig.…”

Section: Spectral Induced Polarization Measurementsmentioning

confidence: 51%

Spectral Induced Polarization of Biochar in Variably Saturated Soil

Gao

Haegel

Esser

et al. 2019

Vadose Zone Journal

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Core Ideas Water retention and spectral induced polarization were measured for biochar in sand. Water retention curves could be fitted by using a dual porosity model. Residual water content was found to increase with the addition of biochar. The polarization of sand–biochar mixtures was much larger than that for sand. Spectral induced polarization may be suitable for monitoring biochar in the field. Biochar is considered a promising soil amendment, but an effective method to detect and characterize the spatial distribution and temporal dynamics of biochar in soil is still missing. The aim of this study is to investigate the ability of the spectral induced polarization (SIP) method for the noninvasive detection of biochar in unsaturated sandy media. In particular, a pure sand and two sand–biochar mixtures with 1 and 2% biochar made from pine (Pinus spp.) wood by pyrolysis at 800°C were investigated. The measured SIP spectra as a function of saturation were interpreted by fitting a Cole–Cole model to the low‐frequency part of the SIP measurements. The porous nature of the biochar particles strongly affected the SIP response of the partially saturated sand–biochar mixtures. Due to the high residual water content of the biochar in a dry background, the relationship between bulk electrical conductivity and water saturation was nonlinear in a log–log representation. This nonlinear behavior could adequately be explained with a dielectric mixing model that considered the drainage of the biochar particles. Both the measured phase and chargeability of the sand–biochar mixtures showed a complex dependence on water saturation. This was attributed to the decrease in polarization strength of the biochar particles with desaturation and the simultaneous increase in phase of the sand background. Overall, the results of this study suggest that field SIP measurements may be a promising tool for the characterization and monitoring of biochar amendments to agricultural soils.

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Section: Spectral Induced Polarization Measurementsmentioning

confidence: 51%

Spectral Induced Polarization of Biochar in Variably Saturated Soil

Gao

Haegel

Esser

et al. 2019

Vadose Zone Journal

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“…Coals with higher microporosity at high coal rank are commonly less permeable for fluid [4], and such a relationship is apparent for coals with high carbon content due to the larger amount of super micropores, micropores and mesopores. The establishment of the pore structure model can further help to understand the microscopic pore development characteristics of reservoir heterogeneity more simply and systematically, which can effectively reflect the mechanism of fluid diffusion and seepage [17], evaluate the fluid permeability of reservoir, and prevent the occurrence of gas burst accidents in "suffocating" coal seam.…”

Section: The Impacts Of Pore Structure On Fluid Transportmentioning

confidence: 99%

Pore Structure of Coals by Mercury Intrusion, N2 Adsorption and NMR: A Comparative Study

Zhu

Yang

et al. 2019

Applied Sciences

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Coalbed methane (CBM) mainly adsorb in massive pores of coal. The accurate characterization of pores benefits CBM resource evaluation, exploration and exploitation. In this paper, mercury intrusion porosimetry (MIP) and low temperature nitrogen adsorption (N2GA) combined with low field nuclear magnetic resonance (NMR) experiments were conducted to analyze the advantages and differences among different experimental techniques in pore characterization. The results show that the total porosity has a tendency to decrease first and then rise with the increase of coal rank, which is mainly caused by the compaction in early stage and the thermogenic gas produced in middle and late stages of coalification. The comparison between different techniques shows that NMR is superior to the conventional methods in terms of porosity and pore size distribution, which should be favorable for pore characterization. The N2GA pore size measurement, based on BJH model, is only accurate within 10‒100 nm in diameter. There is a peak misalignment between the NMR and MIP results in the pore size comparison. The reason for this phenomenon is that there is a centrifugal error in NMR experiment, which could cause a differential damage to the coal sample, resulting in partial loss of the nuclear magnetic signal.

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“…Porosity Measurement. Current methods for measuring material porosity include nitrogen adsorption (see [14]), mercury intrusion (see [4]), impregnation (see [15]), and mass density (see [16]). e pore size of materials with pore size less than 50 nm can be measured by this nitrogen adsorption method, but it is only suitable for ultrafine powder materials.…”

Section: Resultsmentioning

confidence: 99%

“…ese pores will directly affect the properties of the electrospun nanofiber membrane. At present, the methods of measuring the porosity of the electrospun nanofiber membrane include density method, image method, and mercury intrusion method (see [2][3][4]). However, these methods are timeconsuming and costly.…”

Section: Introductionmentioning

confidence: 99%

Fractal Characteristics of Porosity of Electrospun Nanofiber Membranes

Wang

Chen

Dong

et al. 2020

Mathematical Problems in Engineering

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In this paper, the method of measuring the porosity of electrostatic nanofiber membrane by VC++ and Matlab is introduced. It is found that the ratio of the calculated porosity to the porosity measured by the mercury intrusion method accords with the famous Feigenbaum constant (α � 2.5029078750957 · · ·). e porosity distribution of nanofiber membranes was studied by VC++ and Matlab based on the image obtained by using a scanning electron microscope. e porosity distribution calculated by using a computer is magnified by e α times which was named as relative porosity distribution. According to the relative porosity distribution, we use the algorithm proposed by Grassberger and Procaccia (briefly referred to as the G-P algorithm) to calculate the correlation fractal dimension. e correlation fractal dimension calculated from the relative porosity distribution series was between 1 and 2, consistent with geometric characteristics of coincidence samples. e fractal meaning of the Feigenbaum constant was verified again. In the end, we obtained the relationship between the associated fractal dimension and the filtration resistance by fitting in accordance with the secondary function relationship and reached the maximum correlation fractal dimension when the filtration resistance was 15-20 pa.

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A Mercury Intrusion Porosimetry Method for Methane Diffusivity and Permeability Evaluation in Coals: A Comparative Analysis

Cited by 21 publications

References 39 publications

Spectral Induced Polarization of Biochar in Variably Saturated Soil

Spectral Induced Polarization of Biochar in Variably Saturated Soil

Pore Structure of Coals by Mercury Intrusion, N2 Adsorption and NMR: A Comparative Study

Fractal Characteristics of Porosity of Electrospun Nanofiber Membranes

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