Your search keyword '"Klimenko, A. V."' showing total 10 results

1. Tidal and Planetary Waves in the Lower Thermosphere and Ionosphere Simulated with the EAGLE Model for the January 2009 Sudden Stratospheric Warming Conditions

Author

Vasiliev, P. A., Bessarab, F. S., Karpov, I. V., Klimenko, V. V., Klimenko, M. V., Sukhodolov, T. V., and Rozanov, E. V.

Published

2019

2. Energetic Particle Precipitation Influence on Tidal Variations of Thermosphere Parameters in September 2017.

Author

Bessarab, Fedor S., Borchevkina, Olga P., Karpov, Ivan V., Klimenko, Vladimir V., Klimenko, Maxim V., Yakovchuk, Olesya S., Wissing, Jan Maik, and Rozanov, Eugene V.

Subjects

THERMOSPHERE, ATMOSPHERIC ionization, TSUNAMIS, AURORAS, MAGNETIC storms, CHARACTERISTIC functions

Abstract

The role of energetic particle precipitation in the formation of thermospheric tides is investigated. Using the Global Self-consistent Model of the Thermosphere, Ionosphere, and Protonosphere (GSM TIP) and two models of energetic particle precipitation, APM (Auroral Precipitation Model) and AIMOS 2.0.-AISstorm (Atmospheric Ionization Module Osnabrück 2.0—Atmospheric Ionization during Substorms), we performed simulations for the period 3–12 September 2017. This period covers both geomagnetically quiet days and the storm of 7–8 September. The analysis shows that migrating tides diurnal wave (DW) and semidiurnal wave (SW) prevail on quiet days for both versions of the simulations. On the day of maximum storm development on 8 September and the day after—9 September, the nonmigrating components of tidal waves, mainly DW0 and SW0, are intensified. There are also increasing differences in the spatial structure of tides between the two versions of simulations, especially between diurnal and semidiurnal tides at 154 km. On the disturbance days, the amplitudes of diurnal and semidiurnal tides at 154 km in the APM version are markedly greater than the corresponding values in the AIMOS version. Thus, it should be noted that the integral characteristics of the ionization function from precipitations are more important for the formation of DW and SW than its spatial structure or the features of temporal variations. A comparison of the total electron content (TEC) maps for the two versions of the simulation showed that the AIMOS version nicely reproduces the experimental data for a quiet time. The APM version is less accurate for quiet time but simulates the quantitative increase to disturbed conditions at high and middle latitudes better. For model reproduction of observed TEC variations at low and equatorial latitudes, it is not enough to consider the thermospheric source of thermospheric tides. In this case, the role of atmosphere–ionosphere coupling is very important. [ABSTRACT FROM AUTHOR]

Published

2023

3. Application of the models of the middle and upper atmosphere to simulation of total electron content perturbations caused by the 2009 stratospheric warming

Author

Klimenko, M. V., Klimenko, V. V., Bessarab, F. S., Korenkov, Yu. N., Rozanov, E. V., Reddmann, T., Zakharenkova, I. E., and Tolstikov, M. V.

Published

2016

4. Effect of NO concentration disturbances on the global distribution of ionospheric parameters during geomagnetic storms

Author

Koren’kov, Yu. N., Bessarab, F. S., Klimenko, V. V., Klimenko, M. V., and Ratovskii, K. G.

Published

2013

5. Simulation and Observations of the Polar Tongue of Ionization at Different Heights During the 2015 St. Patrick's Day Storms.

Author

Klimenko, Maxim V., Zakharenkova, Irina E., Klimenko, Vladimir V., Lukianova, Renata Yu., and Cherniak, Iurii V.

Subjects

IONIZATION (Atomic physics), SPATIOTEMPORAL processes, PLASMA density, PROTONOSPHERE, GEOMAGNETISM

Abstract

We present the observational and modeling study focused on the major factors determining the spatiotemporal structure of the high‐latitude ionospheric plasma density enhancement—the tongue of ionization (TOI) structure—during the 2015 St. Patrick's Day geomagnetic storm. We use the Global Self‐consistent Model of the Thermosphere, Ionosphere, Protonosphere (GSM TIP) to reproduce the plasma density distribution, and the results are compared with the observational data as deduced from the ground‐based global positioning system total electron content and in situ plasma probe measurements at different altitudes. Both the simulation and observation results show that a large‐scale TOI‐like structure of enhanced plasma density extends from the dayside midlatitude region toward the central polar cap along the antisunward cross‐polar convection flow. We reveal an important role of the clockwise convection cell rotation for the modification of TOI structure. According to model results during the storm main phase, the neutral thermospheric composition, particularly the "tongue" in n(N2), modifies the spatial structure of TOI in such a way that (1) the near‐pole region of enhanced plasma density is shifted to the duskside and, (2) at F region heights, the TOI is split into the dusk and dawn branches. The signature of TOI in the topside ionosphere considerably differs from that in the F region because of a lesser influence of the neutral composition changes at higher altitudes. Model results revealed that at plasmaspheric heights, the TOI structure appears in both the dawn and dusk convection cells. Plain Language Summary: Our paper concerns the investigation and interpretation of high‐latitudinal ionospheric disturbances during the 2015 St. Patrick geomagnetic storm event. Such investigation can be useful for future development of high‐latitudinal upper atmosphere model prediction that is very important for different applications: satellites braking, radio communication, positioning and navigation, and so on. Key Points: At the F region heights, the modeled storm time TOI splits into the dusk and dawn branches due to enhanced molecular nitrogen density in the near‐pole regionClockwise rotation of the two‐cell convection pattern leads to a considerable dawn‐dusk asymmetry of TOI, with a stronger enhancement on the dusksideModel predicts that the TOI‐like region of enhanced ionization at plasmaspheric heights occupies the entire polar cap [ABSTRACT FROM AUTHOR]

Published

2019

6. Ionospheric Effects of the Sudden Stratospheric Warming in 2009: Results of Simulation with the First Version of the EAGLE Model.

Author

Klimenko, M. V., Bessarab, F. S., Sukhodolov, T. V., Klimenko, V. V., Koren’kov, Yu. N., Zakharenkova, I. E., Chirik, N. V., Vasil’ev, P. A., Kulyamin, D. V., Shmidt, Kh., Funke, B., and Rozanov, E. V.

Abstract

In this paper, we discuss perturbations in neutral temperature, total electron content (TEC), and critical frequency of the maximum of the F2 layer (foF2) during the sudden stratospheric warming in January 2009. The calculations were performed using the first version of the EAGLE (Entire Atmosphere Global Model), which is a combination of the models of the low-middle atmosphere (HAMMONIA) and the upper atmosphere (GSM TIP). The EAGLE reproduces observed stratospheric warming and related mesospheric cooling in the northern polar cap in January 2009. At thermospheric altitudes, the neutral temperature perturbations have a quasi-wave character with a wavelength of ∼40 km in the vertical direction. Our results indicate that the HAMMONIA model should be used in the EAGLE instead of the GSM TIP model for the neutral temperature calculations in the altitude region from 80 to 120 km. It is shown that the obtained model foF2 and TEC perturbations are mainly related to seasonal variations. The most-pronounced perturbations in the ionospheric electron density due to stratospheric warming are formed near the equator and are basically negative. Our analysis of the neutral temperature and electron density perturbations made it possible to conclude that the dependence of ionospheric parameters on seasonal changes in solar zenith angle is stronger than for the thermosphere parameters. [ABSTRACT FROM AUTHOR]

Published

2018

7. Global Model of the Thermosphere-Ionosphere-Protonosphere System

Author

Namgaladze, A. A., Korenkov, Yu. N., Klimenko, V. V., Karpov, I. V., Bessarab, F. S., Surotkin, V. A., Glushchenko, T. A., Naumova, N. M., and Korenkov, Jurij N., editor

Published

1988

8. Ionospheric effects caused by the series of geomagnetic storms of September 9-14, 2005.

Author

Klimenko, M. V., Klimenko, V. V., Ratovsky, K. G., and Goncharenko, L. P.

Subjects

*IONOSPHERIC storms, *GEOMAGNETISM, *THERMOSPHERE, *IONOSPHERE, *SOLAR flares

Abstract

This study presents the ionospheric effects caused by the series of geomagnetic storms of September 9-14, 2005. The behavior of different ionospheric parameters over the Yakutsk, Irkutsk, Millstone Hill and Arecibo stations during the considered period have been numerically calculated, using a global self-consistent model of the thermosphere, ionosphere, and protonosphere (GSM TIP) developed at WD IZMI-RAN. The model calculations of disturbances of the ionospheric parameters during storms qualitatively agree with the experimental data at these midlatitude stations. We suggest that the causes of the quantitative differences between the model calculations and the observational data were the use of the 3-hour Kp index of geomagnetic activity and the dipole approximation of geomagnetic field in GSM TIP, with additional contributions from the effects of solar flares which are not considered in GSM TIP. [ABSTRACT FROM AUTHOR]

Published

2011

9. Numerical modeling of the equatorial electrojet UT-variation on the basis of the model GSM TIP.

Author

Klimenko, M. V., Klimenko, V. V., and Bryukhanov, V. V.

Subjects

*EQUATORIAL electrojet, *ATMOSPHERIC electricity, *THERMOSPHERE, *IONOSPHERE, *UPPER atmosphere

Abstract

In the presented work the results of numerical modeling of the UT-variation of the equatorial electrojet, executed on the basis of the model GSM TIP are presented, taking into account the dynamo electric fields generated by thermospheric winds in a current-carrying layer of the ionosphere at heights 80-175 km above a surface of the Earth. To the Global Self-consistent Model of the Thermosphere, Ionosphere and Protonosphere (GSM TIP), developed in WD IZMIRAN, a new block for the calculation of electric fields in the ionosphere has been added. In this block the solution of the three-dimensional equation describing the conservation law of the full current in the Earth's ionosphere is reduced to the solution of the two-dimensional equation by integration along geomagnetic field lines. Calculations of parameters of the near-Earth space plasmas have been executed for quiet equinoctial conditions on 22 March 1987 during the minimum of solar activity. It has been shown, that there is a distinct semidiurnal harmonic in the diurnal behavior of the linear density of the equatorial electrojet with maxima at 23:00 UT and 15:00 UT, as well as with minima at 06:00 UT and 20:00 UT. The greatest and smallest values of the peak intensity of the equatorial electrojet with respect to the diurnal behavior can differ by a factor of two. The longitudinal extent of the area of the equatorial electrojet does hardly show any UT-variation, but the greatest longitudinal extent is at 06 UT. With the growth of the peak intensity of the equatorial electrojet its latitudinal extent also increases (on ~5-10°) a little. At the same time the equatorial electrojet in the maxima of intensity has approximately an identical width, whereas in the minima the electrojet is narrow in the morning and wide in the afternoon. As for the surface density of the equatorial electrojet, its UT-variation is much weaker and equals ~1-3 A/km² and the peak intensity is equal ~15-20 A/km². The latitudinal extent of the surface density of the equatorial electrojet is maximal at 23:00 UT and 15:00 UT and minimal at 06:00 UT and 20:00 UT. [ABSTRACT FROM AUTHOR]

Published

2007

10. Statistical Analysis and Interpretation of High-, Mid- and Low-Latitude Responses in Regional Electron Content to Geomagnetic Storms.

Author

Ratovsky, Konstantin G., Klimenko, Maxim V., Yasyukevich, Yury V., Klimenko, Vladimir V., and Vesnin, Artem M.

Subjects

*MAGNETIC storms, *ATMOSPHERIC models, *UPPER atmosphere, *ELECTRONS, *STATISTICS, *THERMOSPHERE

Abstract

Geomagnetic storm is one of the most powerful factors affecting the state of the Earth's ionosphere. Revealing the significance of formation mechanisms for ionospheric storms is still an unresolved problem. The purpose of the study is to obtain a statistical pattern of the response in regional electron content to geomagnetic storms on a global scale to interpret the results using the upper atmosphere model (the Global Self-consistent Model of the Thermosphere, Ionosphere, and Protonosphere), to make the detailed comparison with the thermospheric storm concept, and to compare the obtained pattern with results from previous statistical studies. The regional electron content is calculated based on the global ionospheric maps data, which allows us to cover the midlatitude and high-latitude zones of both hemispheres, as well as the equatorial zone. Most of the obtained statistical pattern agrees with the thermospheric storm concept and with the previous statistical studies: ionospheric responses at ionospheric storm main phases including their seasonal dependences for the high- and midlatitudes and some features of ionospheric responses at recovery phases. However, some of the statistical patterns are inconsistent with the thermospheric storm concept or contradicts the previous statistical studies: negative midlatitude ionospheric responses at recovery phases in the local winter, the domination of the spring response in the equatorial zone, seasonal features of the positive after-effects, the interhemispheric asymmetry of ionospheric responses, and the prestorm enhancement. We obtained that the contribution of electric field to the interpretation of the zonal and diurnal averaged storm-time regional electron content (REC) disturbances is insignificant. The positive after-storm effects at different latitudes are caused by n(O) disturbances. [ABSTRACT FROM AUTHOR]

Published

2020