AbstractWe study a nonlinear system of partial differential equations that describe rotating shallow water with an arbitrary constant polytropic index γ for the fluid. In our analysis, we apply the theory of symmetries for differential equations, and we determine that the system of our study is invariant under a five-dimensional Lie algebra. The admitted Lie symmetries form the $\left\{{2{A_{1}}{\ \oplus_{s}}\ 2{A_{1}}}\right\}{\ \oplus_{s}}\ {A_{1}}$ Lie algebra for γ ≠ 1 and $2{A_{1}}{\ \oplus_{s}}\ 3{A_{1}}$ for γ = 1. The application of the Lie symmetries is performed with the derivation of the corresponding zero-order Lie invariants, which applied to reduce the system of partial differential equations into integrable systems of ordinary differential equations. For all the possible reductions, the algebraic or closed-form solutions are presented. Travel-wave and scaling solutions are also determined.
Lie symmetries and similarity solutions for a family of 1+1 fifth-order partial differential equations
