RESERVOIR COMPACTION, SUBSIDENCE AND WELL DAMAGE 373
            61   Nur, A. and Byerlee, J.D., “An exact effective stress law for elastic deformation of
                 rock with fluids,” J. Geophys. Res., 76, 1971, p. 6414.
            62   Zimmerman, R.W., Somerton, W.H., and King, M.S., “Compressibility of porous
                 rocks,” J. Geophys. Res., 91, 1986, p. 12, 765.
            63   Biot. M.A., “General theory of three-dimensional consolidation,” J. Appl. Phys., 12,
                 1941, p. 155.
            64   Biot, M.A., “Theory of elasticity and consolidation of a porous anisotropic solid,”
                 J. Appl Phys., 26, 1955, p. 182.
            65   Biot, M.A., “General solutions of the equations of elasticity and consolidation for a
                 porous material,” J. Appl. Mech., 78, 1956, p. 91.
            66   Niot,  M.A.,  “Theory  of  deformation  of  porous  viscoelastic  anisotropic  solid,”  J.
                 Appl. Phys., No. 5, 27, 1956, pp. 459–467.
            67   Biot,  M.A.  and  Willis,  D.G.,  “The  elastic  coefficients  of  the  theory  of
                 consolidation,” J. Appl. Mech., 24, 1957, p. 594.
            68   Rice,  J.R.  and  Cleary,  M.P.,  “Some  basic  stress  diffusion  solutions  for  fluid-
                 saturated  elastic  porous  media  with  compressible  constituents,”  Rev.  Geophys.
                 Space Phys., 14, p. 227.
            69   Oden,  J.T.R.,  Finite  Elements  of  Nonlinear  Continua,  McGraw-Hill,  New  York,
                 1972.
            70   Marsden, I.E. and Hughes, T.J.R., Mathematical Foundations of Elasticity, Dover
                 Publications, Mineaola, NY, 1983.
            71   Green, D.H. and Wang, H.F., “Fluid pressure response to undrained compression in
                 saturated sedimentary rock,” Geophyscis, 51, 4, 1986, pp. 948–956.
            72   Geertsma, J., “The effect of fluid pressure decline on volumetric changes in porous
                 rocks,” Petroleum Transactions of the AIME, 210, 1957, pp. 331–340.
            73   Skempton,  A.W.,  “The  pore  pressure  coefficients  A  and  B,”  Geotechnique,  4,
                 1954, pp. 143–147.
            74   Ostermeier,  R.M.,  “Compaction  effects  on  porosity  and  permeability:  Deepwater
                 Gulf of Mexico turbidites,” Journal of Petroleum Technology, 2001, pp. 68–74.
            75   Martin, J.C. and Serdengecti, S., “Subsidence over oil and gas fields”, in Reviews
                 in  Engineering  Geology,  Volume  VI,  Man-Induced  Land  Subsidence,  T.L.Holzer
                 (ed.), Geological Society of America, Boulder, CO, 1984, pp. 23–34.
            76   Atkinson,  B.K.  (ed.),  Fracture  Mechanics  of  Rock,  Academic  Press,  San  Diego,
                 CA, 1987.
            77   Terzaghi, K., Peck, R.B., and Mesri, G., Soil Mechanics in Engineering Practice,
                 John Wiley, New York, 1996.
            78   Wong, T.F., Szeto, H., and Zhang, J. (1992), “Effect of loading path and porosity
                 on  the  failure  mode  of  porous  rocks,”  Applied  Mechanics  Reviews,  45,  8,
                 pp. 281–293.
            79   Jones,  M.E.  and  Leddra,  M.J.,  “Compaction  and  flow  of  porous  rocks  at  great
                 depth,” Rock at Great Depth, Maury and Fourmaintraux (eds), Balkema, Rotterdam,
                 1989, p. 891.
            80   Yale, D.P. and Crawford, B., “Plasticity and Permeability in carbonate: dependence
                 on  stress  path  and  porosity,”  SPE/ISRM  47852,  Proceedings  SPE/ISRM  Eurock
                 ‘98, 1998, p. 485.
            81   DiMaggio, F.L. and Sandler, I., “Material model for granular soils,” Journal of the
                 Engineering Mechanics Division, ASCE, 97, EMS, 1971, pp. 935–950.