Abstract
Abstract. In order to study the filter effect of the background winds on the propagation of gravity waves, a three-dimensional transfer function model is developed on the basis of the complex dispersion relation of internal gravity waves in a stratified dissipative atmosphere with background winds. Our model has successfully represented the main results of the ray tracing method, e.g. the trend of the gravity waves to travel in the anti-windward direction. Furthermore, some interesting characteristics are manifest as follows: (1) The method provides the distribution characteristic of whole wave fields which propagate in the way of the distorted concentric circles at the same altitude under the control of the winds. (2) Through analyzing the frequency and wave number response curve of the transfer function, we find that the gravity waves in a wave band of about 15–30 min periods and of about 200–400 km horizontal wave lengths are most likely to propagate to the 300-km ionospheric height. Furthermore, there is an obvious frequency deviation for gravity waves propagating with winds in the frequency domain. The maximum power of the transfer function with background winds is smaller than that without background winds. (3) The atmospheric winds may act as a directional filter that will permit gravity wave packets propagating against the winds to reach the ionospheric height with minimum energy loss.
Highlights
(2) Through analyzing the frequency and wave number response curve of the transfer function, we find that the gravity waves in a wave band of about 15–30 min periods and of about 200–400 km horizontal wave lengths are most likely to propagate to the 300-km ionospheric height
We develop a numerical transfer function model based on the linear theory of gravity waves by considering background winds, to study the excitation and propagation of free gravity waves generated in the troposphere and the response of the ionosphere in a realistic atmosphere
Under the linear propagation theory of gravity waves, the transfer function model is built to study the vertical propagation of gravity waves
Summary
The researchers adopt three methods to study the propagation characteristics of gravity waves. Mayr et al (1984, 1990) investigated the characteristics of gravity waves induced by a source in the polar region They did not considered the background winds in their transfer function model, and they did not study free waves excited by a source in the troposphere and did not investigate the characteristics of medium scale gravity waves induced by the local source, such as the weather process, an earthquake and nuclear detonation. We develop a numerical transfer function model based on the linear theory of gravity waves by considering background winds, to study the excitation and propagation of free gravity waves generated in the troposphere and the response of the ionosphere in a realistic atmosphere.
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