TY - JOUR

T1 - Simulation of Propagation of Acoustic-Gravity Waves Generated by Tropospheric Front Instabilities into the Upper Atmosphere

AU - Кшевецкий, Сергей Петрович

AU - Курдяева, Ю.A.

AU - Куличков, С.Н.

AU - Голикова, Е.В

AU - Борчевкина, О.

AU - Гаврилов, Николай Михайлович

N1 - Publisher Copyright: © 2020, Springer Nature Switzerland AG.

PY - 2020/11

Y1 - 2020/11

N2 - A numerical model of the propagation of acoustic-gravity waves excited by pressure fluctuations on the Earth’s surface is developed. Propagation of acoustic-gravity waves generated by instabilities of tropospheric fronts into the upper atmosphere is simulated. The experimental data on atmospheric pressure variations during 2016 year registered on a net of four microbarographs located in the Moscow region are processed. A case of very significant pressure fluctuations (up to 30 times larger than the average level) is selected, which were caused by an atmospheric front arrival. Observed surface pressure field variations for this field were approximated and used as the lower boundary condition for simulating the vertical wave propagation. The numerical simulations showed that just after the boundary source activation, the infrasonic waves in the upper atmosphere may have amplitudes of perturbations of temperature up to 100 K, and horizontal velocity up to 60 m/s. Internal gravity waves come into the upper atmosphere later and far horizontally away from the wave source. The influence of the limited dimensions of the computational domain on the simulation results is investigated. The conditions at the horizontal boundaries of the computational domain, which allow the runaway of waves beyond the domain are proposed. The frequency spectrum of waves in the non-isothermal atmosphere is analyzed

AB - A numerical model of the propagation of acoustic-gravity waves excited by pressure fluctuations on the Earth’s surface is developed. Propagation of acoustic-gravity waves generated by instabilities of tropospheric fronts into the upper atmosphere is simulated. The experimental data on atmospheric pressure variations during 2016 year registered on a net of four microbarographs located in the Moscow region are processed. A case of very significant pressure fluctuations (up to 30 times larger than the average level) is selected, which were caused by an atmospheric front arrival. Observed surface pressure field variations for this field were approximated and used as the lower boundary condition for simulating the vertical wave propagation. The numerical simulations showed that just after the boundary source activation, the infrasonic waves in the upper atmosphere may have amplitudes of perturbations of temperature up to 100 K, and horizontal velocity up to 60 m/s. Internal gravity waves come into the upper atmosphere later and far horizontally away from the wave source. The influence of the limited dimensions of the computational domain on the simulation results is investigated. The conditions at the horizontal boundaries of the computational domain, which allow the runaway of waves beyond the domain are proposed. The frequency spectrum of waves in the non-isothermal atmosphere is analyzed

KW - Numerical simulation

KW - acoustic-gravity waves

KW - atmosphere

KW - atmospheric front

KW - upper atmosphere

KW - BREAKING

KW - PRESSURE

KW - NUMERICAL-MODEL

KW - MECHANISM

KW - MIDDLE ATMOSPHERE

KW - JETS

KW - SURFACE

UR - http://www.scopus.com/inward/record.url?scp=85089994792&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/ccfae297-ecff-39d3-8f4f-31ff1724ab29/

U2 - 10.1007/s00024-020-02569-y

DO - 10.1007/s00024-020-02569-y

M3 - Article

VL - 177

SP - 5567

EP - 5584

JO - Pure and Applied Geophysics

JF - Pure and Applied Geophysics

SN - 0033-4553

IS - 11

ER -