Results of numerical modeling of global distributions of the
horizontal and vertical wind in the Earth's middle atmosphere are presented and
discussed. For obtaining the presented simulation results, the mathematical
model of the global neutral wind system of the Earth’s atmosphere, developed
earlier in the Polar Geophysical Institute, was applied. The peculiarity of the
utilized model consists in that the internal energy equation for the neutral
gas is not solved in the model calculations. Instead, the global temperature
field is assumed to be a given distribution, i.e. the input parameter of the
model. Moreover, in the model calculations, not only the horizontal components
but also the vertical component of the neutral wind velocity is obtained by
means of a numerical solution of a generalized Navier-Stokes equation for
compressible gas, so the applied mathematical model is non-hydrostatic. The
utilized model enables to calculate three-dimensional global distributions of
the zonal, meridional, and vertical components of the neutral wind at levels of
the troposphere, stratosphere, mesosphere, and lower thermosphere. In the
present work the mathematical model is applied for investigation of the
influence of horizontal non-uniformity of the neutral gas temperature on the
formation of the Earth's atmosphere circulation for conditions corresponding to
four different seasons (winter, spring, summer, and autumn). Also, the
mathematical model is applied for investigation of the influence of solar
activity on the formation of the large-scale global circulation of the Earth's
atmosphere. The results of simulation indicate that the horizontal
non-uniformity of the neutral gas temperature, which is distinct in different
seasons, ought to considerably influence the formation of the global neutral
wind system in the middle atmosphere, in particular, the large-scale
circumpolar vortices of the northern and southern hemispheres. Also, the
simulation results indicate that solar activity ought to influence considerably
on the formation of global neutral wind system in the mesosphere and lower
thermosphere. The influence is conditioned by the vertical transport of air
from the lower thermosphere to the mesosphere and stratosphere. This transport
may be rather different under distinct solar activity conditions.
Author(s) Details
Igor V. Mingalev
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
Konstantin G. Orlov
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
Victor S. Mingalev
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
Author(s) Details
Igor V. Mingalev
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
Konstantin G. Orlov
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
Victor S. Mingalev
Polar Geophysical Institute, Russian Academy of Sciences, Academgorodok Str. 26a, Apatity 184209, Murmansk Region, Russia.
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