Abstract
AbstractWe apply spectral stability theory to investigate nonlinear gravity waves in the atmosphere. These waves are determined by modulation equations that result from Wentzel-Kramers-Brillouin theory. First, we establish that plane waves, which represent exact solutions to the inviscid Boussinesq equations, are spectrally stable with respect to their nonlinear modulation equations under the same conditions as what is known as modulational stability from weakly nonlinear theory. In contrast to Boussinesq, the pseudo-incompressible regime does fully account for the altitudinal varying background density. Second,we show for the first time that upward-traveling non-plane wave fronts solving the inviscid nonlinear modulation equations, that compare to pseudo-incompressible theory, are unconditionally unstable. Both inviscid regimes turn out to be ill-posed as the spectra allow for arbitrarily large instability growth rates. Third, a regularization is found by including dissipative effects. The corresponding nonlinear traveling wave solutions have localized amplitude. As a consequence of the nonlinearity, envelope and linear group velocity, as given by the derivative of the frequency with respect to wavenumber, do not coincide anymore. These waves blow up unconditionally by embedded eigenvalue instabilities but the instability growth rate is bounded from above and can be computed analytically. Additionally, all three types of nonlinear modulation equations are solved numerically to further investigate and illustrate the nature of the analytic stability results.
Highlights
Gravity waves have a signi cant impact on the dynamics of the Earth’s atmosphere
We establish that plane waves, which represent exact solutions to the inviscid Boussinesq equations, are spectrally stable with respect to their nonlinear modulation equations under the same conditions as what is known as modulational stability from weakly nonlinear theory
We show for the rst time that upward-traveling non-plane wave fronts solving the inviscid nonlinear modulation equations, that compare to pseudo-incompressible theory, are unconditionally unstable
Summary
Gravity waves have a signi cant impact on the dynamics of the Earth’s atmosphere. Since the resolution and the upper boundary of numerical weather and climate models steadily increase, a better understanding of these waves becomes necessary in order to construct more precise subgrid-scale parametrizations [7]. We want to compute the evolution of the essential spectrum instability of the inviscid traveling wave front numerically to learn about its dynamics For this purpose, the modulation equations (20) are integrated in time with the numerical method presented in appendix A. The region left of the rightmost Fredholm border λ± has ind(LY − λ) = + and belongs to the essential spectrum which is consequentially contained on the right hand side of the complex plane To put it in a nutshell, the dissipative traveling wave packets are unconditionally unstable. The essential spectrum for the upward-traveling wave packet is plotted in gure 6 It consists of a vertical band in the complex plane delimited by the two Fredholm borders, λ+ to the right and λ− to the left. This seemingly paradoxical situation is a logical consequence of the nonlinear nature of these waves
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
