Method of exploiting a sedimentary basin comprising hydrocarbons, by modelling the accumulation of terrestrial organic matter

The invention claimed is: 1. A method of exploiting hydrocarbons within a sedimentary basin, including deposition of inorganic sediments and terrestrial organic matter, which is implemented from property measurements relative to the depositions and to hydrology of the basin, by using for at least one time step a stratigraphic simulator modelling a succession of time steps comprising: A. using the simulator and parameters of the simulator for the at least one time step, with the parameters being constructed from the property measurements to determine a gridded representation representative of at least the distribution of the inorganic sediments within the basin for the at least one time step; B. delimiting at least one unsaturated zone within the basin by using a hydrologic model and parameters of the hydrologic model, with the parameters of the hydrologic model being constructed from the property measurements and the gridded representation; C. determining at least one accumulation zone of the terrestrial organic matter within the basin and an amount of terrestrial organic matter accumulated in the accumulation zone by using an accumulation model of the organic matter and of parameters of the accumulation model, the parameters of the accumulation model comprising a thickness of the unsaturated zone at the at least one time step, stability of the thickness of the unsaturated zone during the at least one time step and the surface water flux at the time step, and from at least an amount of accumulated terrestrial organic matter and the gridded representation quantifying a petroleum potential of the basin, defining an exploitation scheme for the basin and exploiting the basin according to the scheme. 2. A method as claimed in claim 1 , wherein for each cell of the gridded representation at least one property relative to the lithologic facies of the inorganic sediments of the cell is determined by use of the stratigraphic simulator. 3. A method as claimed in claim 2 , wherein the parameters of the hydrologic model comprise hydraulic conductivity in each cell of the gridded representation, the hydraulic conductivity in one of the cells being determined at least from a property relative to lithologic facies of the organic sediments in the cell. 4. A method as claimed in claim 3 , wherein the hydrologic model delimits a saturated zone of the basin by accounting for pressure gradients in the basin and a base of the unsaturated zone is defined by a top of the saturated zone. 5. A method as claimed in claim 4 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 6. A method as claimed in claim 3 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 7. A method as claimed in claim 2 , wherein the hydrologic model delimits a saturated zone of the basin by accounting for pressure gradients in the basin and a base of the unsaturated zone is defined by a top of the saturated zone. 8. A method as claimed in claim 7 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 9. A method as claimed in claim 2 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 10. A method as claimed in claim 1 , wherein the hydrologic model delimits a saturated zone of the basin by accounting for pressure gradients in the basin and a base of the unsaturated zone is defined by a top of the saturated zone. 11. A method as claimed in claim 10 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 12. A method as claimed in claim 1 , wherein a cell of the gridded representation is contained in a zone of potential accumulation of the terrestrial organic matter when a thickness of the unsaturated zone at the at least one time step is at most 1 m and surface water flux is at most 10 m3/s. 13. A method as claimed in claim 12 , wherein a cell of the gridded representation located in a potential accumulation zone belongs to the accumulation zone of the terrestrial organic matter if a thickness of an unsaturated zone in the potential accumulation zone does not vary during the time step. 14. A method as claimed in claim 13 , wherein the unsaturated zone is considered stable when an equality: Su =SR+ SL is verified with SL being an eustatic variation rate, SR being a sedimentation rate relative to deposition of organic sediments and the inorganic sediments, and SU being a subsidence rate. 15. A method as claimed in claim 1 , wherein an amount of accumulated terrestrial organic matter is determined from an accumulation rate TAM of terrestrial organic matter determined with a formula: TAM=Su−SRin−SL with SL being a eustatic variation rate, SRin being a sedimentation rate relative to the deposition of the inorganic sediments, and SU being a subsidence rate. 16. A computer program product storing program code instructions for implementing the method as claimed in claim 1 , when the program is executed on a processor.