2020
DOI: 10.1007/s11430-019-9553-5
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Carbon isotope fractionation during shale gas transport: Mechanism, characterization and significance

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Cited by 38 publications
(32 citation statements)
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“…Canister desorption experimental study about the Longmaxi shale samples at reservoir temperatures showed a rapid enrichment of 13 C up to 13.7‰-16.2‰ in methane as desorption proceeds (Ma et al, 2020). Li et al (2020) proposed to divide the gas transport process during a complete production into four stages and demonstrated that methane became depleted in 13 C during the transition stage (stage II) and became enriched in 13 C during the adsorbed gas desorption stage (stage III), while became depleted in 13 C again during the diffusion stage (stage IV). Carbon isotopic enrichment of methane due to adsorption/desorption during stage IV might contribute to the heavy carbon isotope of methane in Taiyang and Jiaoshiba shale gas fields.…”
Section: Diffusion and Adsorption/desorptionmentioning
confidence: 97%
“…Canister desorption experimental study about the Longmaxi shale samples at reservoir temperatures showed a rapid enrichment of 13 C up to 13.7‰-16.2‰ in methane as desorption proceeds (Ma et al, 2020). Li et al (2020) proposed to divide the gas transport process during a complete production into four stages and demonstrated that methane became depleted in 13 C during the transition stage (stage II) and became enriched in 13 C during the adsorbed gas desorption stage (stage III), while became depleted in 13 C again during the diffusion stage (stage IV). Carbon isotopic enrichment of methane due to adsorption/desorption during stage IV might contribute to the heavy carbon isotope of methane in Taiyang and Jiaoshiba shale gas fields.…”
Section: Diffusion and Adsorption/desorptionmentioning
confidence: 97%
“…CFSR is strongly affected by the sediment source and sedimentary environments [29,30]. Consequently, CFSR is highly heterogeneous, which is primarily manifested in the mineral types, rock compositions, structural characteristics, pore space, organic matter (OM) characteristics, and hydrocarbon mobility [31][32][33][34][35][36]. Some scholars have studied this issue.…”
Section: Introductionmentioning
confidence: 99%
“…4−6 Compared with other direct and indirect methods for the evaluation of gas content, the isotopic composition of methane can provide a more precise calculation method for the gas-in-place content in shale reservoirs and reflect the stage characteristics of gas production. 4,5 In addition, carbon isotopic compositions are also important agents in identifying the origin of shale gas, gas migration patterns, and maturity of shale. 7,8 Isotope fractionation is the phenomenon of differences in chemical or physical behavior of isotopic molecules.…”
Section: Introductionmentioning
confidence: 99%
“…18 This phenomenon is more evident in shale formations with strong gas storage capacity. 4 Moreover, isotope fractionation may also result from the dissolution of methane isotope gas into an aqueous phase due to higher solubility for 13 CH 4 compared to that of 12 CH 4 , but the contribution of dissolution to fractionation can be ignored in shale gas production. 6,11 In addition to adsorption/desorption and dissolution, the discrepancy between transport capacity of isotopic gases during transport through shale pores also results in isotope fractionation.…”
Section: Introductionmentioning
confidence: 99%
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