Abstract FR:

Diffusion processes in soil may be regarded through the classical equations, where gas flows are governed by the concentration gradiant and the distance over which the diffusion occurs. But it can be assumed that, when the biological pores are large enough to be considered similar to the surface, the actual distance, from the surface to one given level into the soil, which governs the gas flow rate is that of the minimum pathway utilizing the most efficient suite of large pores; the length of this pathway is obtained by summing up the respective distances between all the pores belonging to a given suite. The structure of the studied biological pores is a "non connected network". By the first step of simulation, different 3D structures are obtained, over which the minimum pathway is calculated through the simulation of diffusion process: at each time of diffusion progression from the surface, images of the volume concerned by diffusion are obtained. The length of the minimum pathway, depending on the network density and on the mean length of the pores is shown to be 4 to 10 times shorter than the observed distance. The density effect is mean length-dependent; an example of 3D diagram is given to show gas diffusion heterogeneity and gas expanding to the whole sail volume.