Three-dimensional Green’s functions for transversely isotropic poro-chemo-thermoelastic media

• Published in: Archive of applied mechanics (1991) Vol. 93; no. 9; pp. 3427 - 3460
• Main Authors: Shi, Zhouwen, Qi, Shuaixiang, Han, Jiadong, Fu, Longming, Wu, Di
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.09.2023; Springer Nature B.V
• Subjects: Boundary conditions; Classical Mechanics; Cones; Engineering; Green's functions; Holes; Ion sources; Mechanical properties; Original; Porous materials; Porous media; Superposition (mathematics); Theoretical and Applied Mechanics; Conical cavity; Poro-chemo-thermoelastic; Green’s function; Cone
• ISSN: 0939-1533; 1432-0681
• DOI: 10.1007/s00419-023-02448-7

Shale having a porous structure, is sensitive to thermal and chemical stimuli. In order to study the effects of concentrated piont sources on the mechanical behavior of porous materials, we introduce two displacement functions and derive the general solutions of the coupled fields based on the operator theory, superposition principle, and generalized Almansi’s theorem. Two examples are used to introduce the application of general solutions by the liquid-chemical-thermal equilibrium boundary conditions. In the first example, the general solutions are used to solve the problem of semi-infinite transversely isotropic poro-chemo-thermoelastic (PCT) cones subjected to a point fluid source, a point ion source or a point heat source at the vertex. In the other example, the general solutions are used to solve the problem of transversely isotropic PCT media with conical cavities subjected to a point fluid source, a point ion source or a point heat source at the origin. Finally, the contours of the coupled fields of PCT cones and PCT media with a conical cavity are drawn. The numerical results show that the variation of the vertex angle can affect the diffusion trend of the coupled fields.