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This research acknowledges the financial support provided by the National Natural Science Foundation of China (Grant NO. 51508556), Natural Science Foundation of Jiangxi Province (Grant NO. 20232BAB203079 and Grant NO. 20224BAB213045), China University of Mining and Technology-Beijing Inner Mongolia Research Institute Foundation (IMRI23009), Program of China Scholarship Council (Grant NO. 202406430056).

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Molina-Gomez, FaustoAuthorGalindo, RubenCorresponding Author

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Experimental analysis of the damping characteristics of longmaxi shale under graded cyclic loading with different confining pressures

Publicated to:Scientific Reports. 15 (1): 18692- - 2025-05-28 15(1), DOI: 10.1038/s41598-025-03754-6

Authors: Shu, Jiajun; Li, Tao; Li, Yue; Wu, Bingni; Deng, Zhengding; Huang, Jingzhu; Molina-Gomez, Fausto; Galindo, Ruben

Affiliations

China Univ Min & Technol Beijing, Inner Mongolia Res Inst, Ordos 017000, Peoples R China - Author
China Univ Min & Technol Beijing, Sch Mech & Civil Engn, Beijing 100083, Peoples R China - Author
East China Jiaotong Univ, Sch Civil Engn & Architecture, Nanchang 330013, Peoples R China - Author
Jiangxi Univ Sci & Technol, Sch Civil & Surveying & Mapping Engn, Ganzhou 341000, Peoples R China - Author
Univ Politecn Madrid, Higher Tech Sch Civil Engineers, Madrid 28039, Spain - Author
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Abstract

In the process of shale gas field development, the surrounding rock has been in a three-way high-pressure stress state for a long period of time and has undergone complex cyclic loading during hydraulic fracturing and high-pressure fracturing fluid return, and its mechanical response and mechanism of action have important impacts on the stability of the reservoir. To reveal the damping characteristics of Longmaxi shale under different peripheral pressures, graded cyclic loading tests were carried out under 0 MPa, 10 MPa and 30 MPa peripheral pressures to systematically analyze the stress-strain hysteresis characteristics of the shale and the evolution of the damping ratio. The results show that the damping ratio of the Longmaxi shale shows a staged evolution with increasing stress level, which is characterized by "decreasing, stabilizing, and then slightly increasing". During cyclic loading, the axial and radial damping ratios both decreased and stabilized with increasing number of cycles. The radial damping ratio was always greater than the axial damping ratio under the same circumferential pressure conditions, and the difference was more significant under high circumferential pressure conditions. Shale exhibits typical characteristics of hysteresis and damping response evolution during dynamic loading, reflecting a progressive phase shift wherein strain increasingly lags behind stress. This phenomenon primarily arises from the accumulation of plastic deformation, the continuous propagation of microfractures, and the sequential activation of multistage energy dissipation mechanisms. The damping ratio follows a staged evolution pattern characterized by an initial decline, a period of stability, and a final surge. This trend indicates a transition in the material's response mechanism-from being dominated by structural compaction to being governed by microscopic damage processes.

Keywords

Confining pressuresDamping characterizationGraded cyclic loadingHysteresis curvHysteresis curveLongmaxi shaleMechanical-propertiesModeRock

Quality index

Bibliometric impact. Analysis of the contribution and dissemination channel

The work has been published in the journal Scientific Reports due to its progression and the good impact it has achieved in recent years, according to the agency WoS (JCR), it has become a reference in its field. In the year of publication of the work, 2025, it was in position 25/134, thus managing to position itself as a Q1 (Primer Cuartil), in the category Multidisciplinary Sciences.

Leadership analysis of institutional authors

This work has been carried out with international collaboration, specifically with researchers from: China.

There is a significant leadership presence as some of the institution’s authors appear as the first or last signer, detailed as follows: First Author (Shu, Jiajun) and Last Author (GALINDO AIRES, RUBEN ANGEL).

the authors responsible for correspondence tasks have been Shu, Jiajun and GALINDO AIRES, RUBEN ANGEL.