Lie Symmetries for the Shallow Water Magnetohydrodynamics Equations in a Rotating Reference Frame

Abstract

We perform a detailed Lie symmetry analysis for the hyperbolic system of partial differential equations that describe the one-dimensional Shallow Water magnetohydrodynamics equations within a rotating reference frame. We consider a relaxing condition ∇ ( hB ) ≠ 0 for the one-dimensional problem, which has been used to overcome unphysical behaviors. The hyperbolic system of partial differential equations depends on two parameters: the constant gravitational potential g and the Coriolis term f0, related to the constant rotation of the reference frame. For four different cases, namely g=0,~f0=0; g≠ 0\,,~f0=0; g=0, f0≠ 0; and g≠ 0, f0≠ 0 the admitted Lie symmetries for the hyperbolic system form different Lie algebras. Specifically the admitted Lie algebras are the L10=\ A3,3 A2,1\ sA5,34a; % L8=A2,1 A6,22; L7=A3,5\ A2,1 A2,1\ ; and L6=A3,5 A3,3~respectively, where we use the Morozov-Mubarakzyanov-Patera classification scheme. For the general case where f0g≠ 0, we derive all the invariants for the Adjoint action of the Lie algebra L6 and its subalgebras, and we calculate all the elements of the one-dimensional optimal system. These elements are then considered to define similarity transformations and construct analytic solutions for the hyperbolic system.

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