Mechanical and hydraulic transport properties of transverse-isotropic Gneiss deformed under deep reservoir stress and pressure conditions.

"This is the ReadMe file corresponding to the study entitled: "Mechanical and hydraulic transport properties of transverse-isotropic Gneiss deformed under deep reservoir stress and pressure conditions"          "By M. Acosta, & M. Violay."          This study has been published in the International Journal of Rock Mechanics and Mining Sciences in June 2020.      https://doi.org/10.1016/j.ijrmms.2020.104235      This Read-Me file has been last edited on 2020-06-31          This readme file describes the data repository and supplementary files accompanying the above publication.       For any further queries please contact mateo.acosta@epfl.ch          The following files are included:          --- Regarding Figure 3.          "1)  ""Acosta_et_al_2020_Figure3Data.xlsx"" "     This is the processed data from the experiments described in Figure1 of the article.     "In this .xlsx File, each sheet corresponds to one figure panel as follows: "          Fig.3: One experiment example Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); --- Regarding Figure 4.          "1)  ""Acosta_et_al_2020_Figure4Data.xlsx"" "     This is the processed data from the experiments described in Figure1 of the article.     "In this .xlsx File, each sheet corresponds to one figure panel as follows: "          Fig.4a&g: Beta=0deg Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); Fig.4b&h: Beta=30deg Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); Fig.4c&i: Beta=45deg Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); Fig.4d&j: Beta=60deg Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); Fig.4e&k: Beta=90deg Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); Fig.4f&l: LPG Column A: Axial strain in (%) ; Column B: Effective axial stress (in MPa); Column C: Axial strain for AE's in (%) ; Column D: Acoustic emission hits (in #); Column D: Axial strain for porosity change in (%) ; Column E: Porosity change (in %); --- Regarding all other Figures, the tables provided in the article allow reproduction of these.