2019
DOI: 10.1007/s00205-019-01422-4
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Stability of Hydraulic Shock Profiles

Abstract: We establish nonlinear H 2 ∩ L 1 → H 2 stability with sharp rates of decay in L p , p ≥ 2, of general hydraulic shock profiles, with or without subshocks, of the inviscid Saint-Venant equations of shallow water flow, under the assumption of Evans-Lopatinsky stability of the associated eigenvalue problem. We verify this assumption numerically for all profiles, giving in particular the first nonlinear stability results for shock profiles with subshocks of a hyperbolic relaxation system.An interesting open proble… Show more

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Cited by 14 publications
(23 citation statements)
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“…where h denotes fluid height; q = hu total flow, with u fluid velocity; and F > 0 the Froude number, a nondimensional parameter depending on reference height/velocity and inclination. Following [29], we here focus on the hydrodynamically stable case 0 < F < 2, and associated hydraulic shock profile solutions (5.2) These are piecwise smooth traveling-wave solutions satisfying the Rankine-Hugoniot jump and Lax entropy conditions at any discontinuities. Their existence theory reduces to the study of an explicitly solvable scalar ODE with polynomial coefficients [29] We now turn to the discussion of stability.…”
Section: Applicationmentioning
confidence: 99%
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“…where h denotes fluid height; q = hu total flow, with u fluid velocity; and F > 0 the Froude number, a nondimensional parameter depending on reference height/velocity and inclination. Following [29], we here focus on the hydrodynamically stable case 0 < F < 2, and associated hydraulic shock profile solutions (5.2) These are piecwise smooth traveling-wave solutions satisfying the Rankine-Hugoniot jump and Lax entropy conditions at any discontinuities. Their existence theory reduces to the study of an explicitly solvable scalar ODE with polynomial coefficients [29] We now turn to the discussion of stability.…”
Section: Applicationmentioning
confidence: 99%
“…Following [29], we here focus on the hydrodynamically stable case 0 < F < 2, and associated hydraulic shock profile solutions (5.2) These are piecwise smooth traveling-wave solutions satisfying the Rankine-Hugoniot jump and Lax entropy conditions at any discontinuities. Their existence theory reduces to the study of an explicitly solvable scalar ODE with polynomial coefficients [29] We now turn to the discussion of stability. Linearizing (5.1) about a smooth profile (H, Q) following [18,26], we obtain eigenvalue equations…”
Section: Applicationmentioning
confidence: 99%
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