A multi-scale and multi-mechanism coupled model for carbon isotope fractionation of methane during shale gas production

IF 6.1 1区工程技术 Q2 ENERGY & FUELS

Petroleum Science Pub Date : 2025-07-01 DOI:10.1016/j.petsci.2025.03.034

Jun Wang , Fang-Wen Chen , Wen-Biao Li , Shuang-Fang Lu , Sheng-Xian Zhao , Yong-Yang Liu , Zi-Yi Wang

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引用次数: 0

Abstract

Prediction of production decline and evaluation of the adsorbed/free gas ratio are critical for determining the lifespan and production status of shale gas wells. Traditional production prediction methods have some shortcomings because of the low permeability and tightness of shale, complex gas flow behavior of multi-scale gas transport regions and multiple gas transport mechanism superpositions, and complex and variable production regimes of shale gas wells. Recent research has demonstrated the existence of a multi-stage isotope fractionation phenomenon during shale gas production, with the fractionation characteristics of each stage associated with the pore structure, gas in place (GIP), adsorption/desorption, and gas production process. This study presents a new approach for estimating shale gas well production and evaluating the adsorbed/free gas ratio throughout production using isotope fractionation techniques. A reservoir-scale carbon isotope fractionation (CIF) model applicable to the production process of shale gas wells was developed for the first time in this research. In contrast to the traditional model, this model improves production prediction accuracy by simultaneously fitting the gas production rate and δ¹³C₁ data and provides a new evaluation method of the adsorbed/free gas ratio during shale gas production. The results indicate that the diffusion and adsorption/desorption properties of rock, bottom-hole flowing pressure (BHP) of gas well, and multi-scale gas transport regions of the reservoir all affect isotope fractionation, with the diffusion and adsorption/desorption parameters of rock having the greatest effect on isotope fractionation being D∗/D, P_L, V_L, α, and others in that order. We effectively tested the universality of the four-stage isotope fractionation feature and revealed a unique isotope fractionation mechanism caused by the superimposed coupling of multi-scale gas transport regions during shale gas well production. Finally, we applied the established CIF model to a shale gas well in the Sichuan Basin, China, and calculated the estimated ultimate recovery (EUR) of the well to be 3.33 × 10⁸ m³; the adsorbed gas ratio during shale gas production was 1.65%, 10.03%, and 23.44% in the first, fifth, and tenth years, respectively. The findings are significant for understanding the isotope fractionation mechanism during natural gas transport in complex systems and for formulating and optimizing unconventional natural gas development strategies.

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页岩气生产过程甲烷碳同位素分馏多尺度多机制耦合模型

预测产量下降和评估吸附/游离气比对于确定页岩气井的寿命和生产状态至关重要。由于页岩的低渗透性、低密闭性、多尺度输气区和多种输气机制叠加的复杂流动特征以及页岩气井生产状态的复杂多变，传统的产量预测方法存在一定的不足。最近的研究表明，页岩气生产过程中存在多阶段同位素分馏现象，每一阶段的分馏特征与孔隙结构、原地气（GIP）、吸附/解吸以及产气过程有关。该研究提出了一种利用同位素分馏技术估算页岩气井产量和评估整个生产过程中吸附/游离气比的新方法。本文首次建立了适用于页岩气井生产过程的储层尺度碳同位素分馏（CIF）模型。与传统模型相比，该模型通过同时拟合产气量和δ13C1数据，提高了产量预测精度，为页岩气生产过程中吸附/游离气比的评价提供了一种新的方法。结果表明：岩石的扩散和吸附/解吸特性、气井井底流动压力（BHP）以及储层的多尺度输气区均影响同位素分馏，其中岩石的扩散和吸附/解吸参数对同位素分馏影响最大的依次为D * /D、PL、VL、α。有效验证了四阶段同位素分馏特征的普适性，揭示了页岩气井生产过程中多尺度输气区叠加耦合形成的独特同位素分馏机制。最后，将建立的CIF模型应用于四川盆地的页岩气井，计算出该井的估计最终采收率（EUR）为3.33 × 108 m3；页岩气第1年、第5年和第10年的吸附气比分别为1.65%、10.03%和23.44%。研究结果对于理解复杂系统中天然气输运过程中同位素分馏机理，制定和优化非常规天然气开发策略具有重要意义。

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来源期刊

Petroleum Science 地学-地球化学与地球物理

CiteScore

7.70

自引率

16.10%

发文量

311

审稿时长

63 days

期刊介绍： Petroleum Science is the only English journal in China on petroleum science and technology that is intended for professionals engaged in petroleum science research and technical applications all over the world, as well as the managerial personnel of oil companies. It covers petroleum geology, petroleum geophysics, petroleum engineering, petrochemistry & chemical engineering, petroleum mechanics, and economic management. It aims to introduce the latest results in oil industry research in China, promote cooperation in petroleum science research between China and the rest of the world, and build a bridge for scientific communication between China and the world.