TY - JOUR
T1 - Nonlinear Advection–Diffusion–Reaction Phenomena Involved in the Evolution and Pumping of Oil in Open Sea
T2 - Modeling, Numerical Simulation and Validation Considering the Prestige and Oleg Naydenov Oil Spill Cases
AU - Ivorra, Benjamin
AU - Gomez, Susana
AU - Glowinski, Roland
AU - Ramos, Angel Manuel
N1 - Funding Information:
This work was carried out thanks to the financial support of the Spanish "Ministry of Economy and Competitiveness" under project MTM2011-22658; the research group MOMAT (Ref. 910480) supported by "Banco Santander" and "Universidad Complutense de Madrid"; the "Junta de Andaluc??a" and the European Regional Development Fund through Project P12-TIC301; the "European Space Agency" through Project 14161; the research center "Mercator Ocean" trough Project 2012_130/NCUTD/59; the Spanish "Agencia Estatal de Meteorolog??a" trough project 990130301; and the PAPIIT project of the National University of Mexico. We would like to thank the Spanish agency "Puerto de Estados", the company "Novetec" and Nelson del Castillo for their valuable help during this work.
PY - 2017/3/1
Y1 - 2017/3/1
N2 - The main goal of this article is to improve upon a previous model used to simulate the evolution of oil spots in the open sea and the effect of a skimmer ship pumping oil out from the spots. The concentration of the pollutant is subject to the effects of wind and sea currents, diffusion, and the pumping action of a skimmer (i.e., cleaning) ship that follows a pre-assigned trajectory. This implies that the mathematical model is of the advection–diffusion–reaction type. A drawback of our previous model was that diffusion was propagating with infinite velocity; in this article, we use an improved model relying on a nonlinear diffusion term, implying that diffusion propagates with finite velocity. To reduce numerical diffusion when approximating the advection part of the model, we consider second order discretization schemes with nonlinear flux limiters. We consider also absorbing boundary conditions to insure accurate results near the boundary. To reduce CPU time we use an operator-splitting scheme for the time discretization. Finally, we also introduce the modeling of coastlines and dynamic sources of pollutant. The novel approach we advocate in this article is validated by comparing our numerical results with real life measurements from the Oleg Naydenov and the Prestige oil spills, which took place in Spain in 2015 and 2002, respectively.
AB - The main goal of this article is to improve upon a previous model used to simulate the evolution of oil spots in the open sea and the effect of a skimmer ship pumping oil out from the spots. The concentration of the pollutant is subject to the effects of wind and sea currents, diffusion, and the pumping action of a skimmer (i.e., cleaning) ship that follows a pre-assigned trajectory. This implies that the mathematical model is of the advection–diffusion–reaction type. A drawback of our previous model was that diffusion was propagating with infinite velocity; in this article, we use an improved model relying on a nonlinear diffusion term, implying that diffusion propagates with finite velocity. To reduce numerical diffusion when approximating the advection part of the model, we consider second order discretization schemes with nonlinear flux limiters. We consider also absorbing boundary conditions to insure accurate results near the boundary. To reduce CPU time we use an operator-splitting scheme for the time discretization. Finally, we also introduce the modeling of coastlines and dynamic sources of pollutant. The novel approach we advocate in this article is validated by comparing our numerical results with real life measurements from the Oleg Naydenov and the Prestige oil spills, which took place in Spain in 2015 and 2002, respectively.
KW - Advection–diffusion–reaction equations
KW - Finite volume schemes
KW - Nonlinear diffusion
KW - Operator-splitting
KW - Sea pollution
UR - http://www.scopus.com/inward/record.url?scp=84984834093&partnerID=8YFLogxK
U2 - 10.1007/s10915-016-0274-x
DO - 10.1007/s10915-016-0274-x
M3 - Journal article
AN - SCOPUS:84984834093
SN - 0885-7474
VL - 70
SP - 1078
EP - 1104
JO - Journal of Scientific Computing
JF - Journal of Scientific Computing
IS - 3
ER -