K.F. Gu scite author profile

K.F. Gu

2Publications

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31Citation Statements Given

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Geomechanical Modeling of Stress and Fracture Distribution during Contractional Fault-Related Folding

Gu¹

2017

GEP

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Understanding and predicting the distribution of fractures in the deep tight sandstone reservoir are important for both gas exploration and exploitation activities in Kuqa Depression. We analyzed the characteristics of regional structural evolution and paleotectonic stress setting based on acoustic emission tests and structural feature analysis. Several suites of geomechanical models and experiments were developed to analyze how the geological factors influenced and controlled the development and distribution of fractures during folding. The multilayer model used elasto-plastic finite element method to capture the stress variations and slip along bedding surfaces, and allowed large deformation. The simulated results demonstrate that this novel Quasi-Binary Method coupling composite failure criterion and geomechanical model can effectively quantitatively predict the developed area of fracture parameters in fault-related folds. High-density regions of fractures are mainly located in the fold limbs during initial folding stage, then gradually migrate from forelimb to backlimb, from limbs to hinge, from deep to shallow along with the fold uplift. Among these factors, the fold uplift and slip displacement along fault have the most important influence on distributions of fractures and stress field, meanwhile the lithology and distance to fault have also has certain influences. When the uplift height exceeds approximately 55 percent of the total height of fold the facture density reaches a peak, which conforms to typical top-graben fold type with large amplitude and high-density factures in the top. The overall simulated results match well with core observation and FMI results both in the whole geometry and fracture distribution.

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Electric field Induced phase transformation In ceramics

Fantozzi

Olagnon²,

Lecuir³

et al.

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It is known that: (1) an analogy exists between the electrical and mechanical properties of dielectric materials, (2) the polarization energy can be dissipated via phase transitions, and (3) phase transformation produced in ceramics under mechanical stress or at the time of crack propagation, increases fracture toughness. The influence of an electric field on the structure of an alumina (Al2O3) ceramic, with Zr02 (20%) is reported. It is shown that: (a) the percentage of Zr02 undergoing phase transformation from tetragonal to monolithic (t-->m) depends on the amplitude and duration of the applied electric field, (b) the phase transformation plays a dominant role on the conditionning of the insulator, (c) the sintering method influences the (t-->m) rate. The results presented will provide original insights into the conditionning mechanism, partial discharge mechanism, flashover, and on the role of internal stresses on voltage withstand of dielecrics.Electric field induced phase transformation have been reported in polymers /1/ in the frame of study of electrets formed in dielectrics submitted to poling. Electric field induced phase transformation is one possible mechanism for dielectric relaxation /U. Relaxation involves transfer of electrostatic energy to the phonon bath and can induce second order or first order phase transformation. However, the investigation of dielectric relaxation processes in solids have shown a clear analogy between electrical properties and mechanical properties./2/ The effect of electrets and related dielectric relaxation processes on electrical breakdown phenomena (flashover, punchthrough, bulk breakdown) has been recently shown /3,4/. The effect of electrets created by poling or UV irradiation on fracture toughness has been demonstrated on Yttria /5/. The effect of electrets on both toughness and breakdown voltage can be justified on the thermodynamical concept of first order phase transformation (see ref.1, p.18 and /6/). The aim of this work is therfore to investigate phase transformation of ceramics induced by electrets produced by poling. The target is also (i) to show that electrical conditioning of insulators can be related to such phase

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K.F. Gu

Geomechanical Modeling of Stress and Fracture Distribution during Contractional Fault-Related Folding

Electric field Induced phase transformation In ceramics

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