%0 Journal Article
%T Streamline-based reactive transport modeling of uranium mining during in-situ leaching: Advantages and drawbacks
%A Kurmanseiit, M. B.
%A Tungatarova, M. S.
%A Royer, J-J
%A Aizhulov, D. Y.
%A Shayakhmetov, N. M.
%A Kaltayev, A.
%J Hydrometallurgy
%D 2023
%V 220
%@ 0304-386x
%F Kurmanseiit_etal2023
%O exported from refbase (http://www.uhydro.de/base/show.php?record=190), last updated on Fri, 26 Jan 2024 13:19:04 +0100
%X Reactive transport modeling is known to be computationally intensive when applied to 3D problems. Transforming sequential computing on the computer processor units (CPU) into parallelized computation on the high-performance parallel graphic processor units (GPU) is a classical approach to increasing computational performance. Another complementary approach is to decompose a complex 3D modeling problem into a set of simpler 1D problems using streamline approaches which can be easily parallelized, therefore reducing computation time. This paper investigates solutions to the equations governing dissolution and transport using streamlines coupled with a parallelization approach. In addition, an analytical solution to the dissolution and transfer equations of uranium describing the In-Situ Leaching (ISL) mining recovery is found using an approximation series to the 2nd order. The analytical solution is compared to the 1D numerical resolution along the streamlines and to the 3D simulation results superimposed on the streamline. Both approaches give similar results with a relative error of \textless2 % (2%). The proposed methodology is then applied to a case study in which the classical 3D resolution is compared to the newly suggested streamline solution, demonstrating that the streamline approach increases computational performances by a factor ranging from hundred to thousand depending on the complexity of the grid-block model.
%K 3D modeling
%K In-situ leaching
%K Reactive transport model
%K Streamlines
%K Uranium recovery
%U https://www.sciencedirect.com/science/article/pii/S0304386X23000890
%P 106107